Nonapplicable.
The present invention relates generally to rockets, rocket engines, and cooling systems relating to rocket pump motors and rocket engines. More specifically, the present invention relates to improved rocket engine systems with an independently-regulated cooling system.
The Applicant is unaware of inventions or patents, taken either singly or in combination, which are seen to describe the instant invention as claimed.
The present invention relates to improved rocket engines with a supercritical coolant.
An improved rocket engine with a supercritical coolant comprises a coolant source, a propellant source, a pressurization system, and a heat exchanger. Each of the coolant source and propellant source is in operative communication with the pressurization system whereby the coolant is pressurized and then heated by a heat exchanger to a supercritical state.
In one embodiment, the propellant source comprises a fuel source, an oxidizer source which may be pre-mixed with the fuel source, and a coolant source, which coolant may be fuel, oxidizer, or inert.
One embodiment of the rocket engine comprises a cooling system with a coolant source, a fuel system with a fuel source, an oxidizer system with an oxidizer source, a propellant pressurizing system with a propellant pressurizing source, a heat exchanger, and the pressurization source driven by the coolant after it passes through the rocket engine and heat exchanger (expander cycle).
Another embodiment of the improved rocket engine system comprises a cooling system with a coolant source, a fuel system with a fuel source, an oxidizer system with an oxidizer source, a propellant pressurizing system with a propellant pressurizing source, a heat exchanger, a pressurization source driven by the coolant after it passes through the rocket engine and heat exchanger (expander cycle), and an aerospike nozzle which is cooled by the coolant after the it has powered the pressurization system.
A further embodiment of the improved rocket engine system comprises a cooling system with a coolant source, a fuel system with a fuel source, an oxidizer system with an oxidizer source, a propellant pressurizing system with a propellant pressurizing source, a preburner, and a pressurization source driven by the coolant after it passes through the rocket engine and heat exchanger (expander cycle). The preburner is a side combustion reaction between the fuel and oxidizer to generate supercritical coolant.
These and other characteristics of the present invention will be more fully understood by reference to the following detailed description in conjunction with the attached drawings, in which:
Referring to
Referring to
The coolant temperature is increased in the heat exchanger 11 to a supercritical state and the supercritical coolant is then in communication with coolant channels, also called cowls, built into the outer walls via the coolant heat exchanger outlet line 12. In one embodiment, the supercritical state is temperature and pressure just into the supercritical regime of the coolant used. For example, if water is used as the supercritical coolant, the temperature may be raised to between 374-392° C., and the pressure to between 220-231 bar. The coolant may thus be raised to a just-supercritical state, just above the critical pressure and temperature, where there is a significant increase in convective heat transfer due to the lower viscosity and higher conductivity of the fluid. The internal coolant channels are integrated into the wall via manifolds and passages as those skilled in the art are familiar with. The coolant cools the engine walls including the throat 6 and portion of the nozzle 2 before returning to the heat exchanger 11 via the hot coolant inlet 13. The coolant after exchanging heat with the incoming coolant, exits the heat exchanger 11 and enters the coolant turbine 15 via the hot coolant heat exchanger outlet 14. After the coolant provides the power for the pressurization system, the coolant enters the injector manifold 10 via the turbine outlet line 20, and enters the combustion chamber 3 with the fuel and propellant and exits the rocket engine through the throat 6.
Referring to
In this embodiment there are coolant channels 4 in the inner cowl 5 and coolant channels 21 in the outer cowl 1. Coolant from the heat exchanger outlet 12 first cools the inner cowl 5 via coolant channels 4 before returning to the heat exchanger 11 via the hot coolant heat exchanger inlet 13. The hot coolant after exchanging heat with the incoming coolant, exits the heat exchanger 11 and enters the coolant turbine 15 via the hot coolant heat exchanger outlet 14. After the coolant turbine 15 the coolant returns to the aerospike engine and cools the outer cowl 1 via coolant channels 21. The coolant channels 4 and 21 are integrated into the cowls via manifolds and passages as those skilled in the art are familiar with. After the coolant provides the power for the pressurization system, the coolant enters the injector manifold 10 via the turbine outlet line 20, and enters the combustion chamber annulus 3 with the fuel and propellant and exits the rocket engine through the throat 6.
Referring to
Referring to
Element 30 in drawings is a rocket engine embodiment.
Element 31 in drawings is a block of hardware that includes plumbing as necessary, as is known in the art.
“Rocket engine” and “rocket engine system” are generally equivalent terms.
“Cowl” and “wall” of a combustion chamber are generally equivalent terms.
“Fuel source,” “oxidizer source,” and “coolant source” are generally equivalent terms with “fuel input,” “oxidizer input,” and “coolant input” respectively. These sources/inputs may be described as “feedlines.”
“Passages,” “channels” and “cowls” are generally equivalent terms.
“Turbopump” and “turbine” are generally equivalent terms.
The convection heat flux, q=hΔT, into the coolant is proportional to the convection coefficient h and temperature difference ΔAT=Tcombustion−Tcoolant. In a supercritical state, the convection coefficient h increases significantly due to decreased viscosity and increased thermal conductivity of the coolant. The total heat transfer increases, even though the coolant temperature Tcoolant has increased giving a subsequent decrease in ΔT. Thus the rocket engine can be cooled much more effectively and efficiently.
This application claims priority to and the benefit of provisional patent application no. 63/130,586 filed Dec. 24, 2020 by the present inventor and non-provisional application no. 17/561,623.
Number | Date | Country | |
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63130586 | Dec 2020 | US |