WO2009062183A1 - Nitrous oxide fuel blend monopropellants - Google Patents
Nitrous oxide fuel blend monopropellants Download PDFInfo
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- WO2009062183A1 WO2009062183A1 PCT/US2008/083039 US2008083039W WO2009062183A1 WO 2009062183 A1 WO2009062183 A1 WO 2009062183A1 US 2008083039 W US2008083039 W US 2008083039W WO 2009062183 A1 WO2009062183 A1 WO 2009062183A1
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- monopropellant
- nofb
- monopropellants
- oxidizer
- nitrous oxide
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- C—CHEMISTRY; METALLURGY
- C06—EXPLOSIVES; MATCHES
- C06B—EXPLOSIVES OR THERMIC COMPOSITIONS; MANUFACTURE THEREOF; USE OF SINGLE SUBSTANCES AS EXPLOSIVES
- C06B47/00—Compositions in which the components are separately stored until the moment of burning or explosion, e.g. "Sprengel"-type explosives; Suspensions of solid component in a normally non-explosive liquid phase, including a thickened aqueous phase
- C06B47/02—Compositions in which the components are separately stored until the moment of burning or explosion, e.g. "Sprengel"-type explosives; Suspensions of solid component in a normally non-explosive liquid phase, including a thickened aqueous phase the components comprising a binary propellant
- C06B47/04—Compositions in which the components are separately stored until the moment of burning or explosion, e.g. "Sprengel"-type explosives; Suspensions of solid component in a normally non-explosive liquid phase, including a thickened aqueous phase the components comprising a binary propellant a component containing a nitrogen oxide or acid thereof
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- C—CHEMISTRY; METALLURGY
- C06—EXPLOSIVES; MATCHES
- C06D—MEANS FOR GENERATING SMOKE OR MIST; GAS-ATTACK COMPOSITIONS; GENERATION OF GAS FOR BLASTING OR PROPULSION (CHEMICAL PART)
- C06D5/00—Generation of pressure gas, e.g. for blasting cartridges, starting cartridges, rockets
- C06D5/08—Generation of pressure gas, e.g. for blasting cartridges, starting cartridges, rockets by reaction of two or more liquids
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- C—CHEMISTRY; METALLURGY
- C10—PETROLEUM, GAS OR COKE INDUSTRIES; TECHNICAL GASES CONTAINING CARBON MONOXIDE; FUELS; LUBRICANTS; PEAT
- C10L—FUELS NOT OTHERWISE PROVIDED FOR; NATURAL GAS; SYNTHETIC NATURAL GAS OBTAINED BY PROCESSES NOT COVERED BY SUBCLASSES C10G, C10K; LIQUEFIED PETROLEUM GAS; ADDING MATERIALS TO FUELS OR FIRES TO REDUCE SMOKE OR UNDESIRABLE DEPOSITS OR TO FACILITATE SOOT REMOVAL; FIRELIGHTERS
- C10L3/00—Gaseous fuels; Natural gas; Synthetic natural gas obtained by processes not covered by subclass C10G, C10K; Liquefied petroleum gas
- C10L3/02—Compositions containing acetylene
Definitions
- Liquid fueled rockets have better specific impulse (l sp ) than solid rockets and are capable of being throttled, shut down and restarted
- the primary performance advantage of liquid propellants is the oxidizer
- oxidizers liquid oxygen, nitrogen tetroxide and hydrogen peroxide
- Oxidizers are generally at least moderately difficult to store and handle, either due to extreme toxicity (nitric acids), moderate cryogenicity (liquid oxygen) or both (liquid fluorine)
- Oxidizers that have been proposed, for example, O 3 , CIF 3 , CIF 5 , are unstable, energetic and toxic
- this reaction generates 82 kJ/mol (515 Whr/kg) of heat per unit nitrous oxide.
- To liquefy the stored monopropellant requires 16.5 kJ/mol (104 Whr/kg) or approximately 20% of the enthalpy of reaction.
- the maximum theoretical l sp of this reaction is 205s.
- ⁇ 2 O is a highly stable molecule given its high activation energy barrier -250 kJ/mol.
- thermal decomposition requires preheat temperatures >1000°C.
- catalysts can be used to significantly depress this activation energy.
- the hot (>1500°C) make catalyst bed and reaction chamber design challenging.
- the specific energy density of liquid monopropellants can be increased up to -1500 Whr/kg (-3 times the energy density of pure N 2 O), and l sp performance greater than 300 s becomes feasible.
- the hot deleterious oxygen in the exhaust stream can be consumed and the higher combustion reaction temperatures result in faster reaction kinetics as compared to pure N 2 O decomposition.
- the faster kinetics permit rapid spark ignition.
- a catalyst bed does not become the material limitation for engine design, and regeneratively cooled engine design approaches with conventional materials can be adapted for the higher l sp performance using low cost engine fabrication techniques.
- nitrous oxide fuel blend monopropellants comprising organic fuels mixed with nitrous oxide (N 2 O)
- the nitrous oxide provides both thermal decomposition energy and serves as the oxidizer to combust the fuels
- Example organic fuels include ethane (C 2 H 6 ), ethylene (C 2 H 4 ), acetylene (C 2 H 2 ), and mixtures thereof
- O/F oxidizer-to-fuel ratio
- desired monopropeilant characteristics including, but not limited to, l sp , miscibility over a wide temperature and pressure range, favorable fluid handling performance, low freezing points, rapid combustion kinetics for fast engine response times, relatively high thermal decomposition limits, low mechanical shock sensitivity and impact-induced detonation, relatively high storage densities, and exhaust gas chemistries that do not produce carbon fouling or hot oxidizing environments that are difficult,
- the organic compound comprises, as a main component, a C2 hydrocarbon, or mixtures of C2 hydrocarbons.
- a monopropellant comprising nitrous oxide and acetylene in an oxidizer-to-fuel ratio of about 2.5 to about 1 1 0, or about 3.0 to about 9 0, or about 4.0 to about 8 0, or about 4.5 to about 7 5, or about 2 5 to about 6 0, or about 3.0 to about 5 0, or about 6.0 to about 11 0, or about 8 0 to about 10 0.
- NOFB monopropellants comprising nitrous oxide and ethane in an oxidizer-to-fuel ratio of about 2 5 to about 1 1.0, or about 3.0 to about 9.0, or about 4 0 to about 8.0, or about 4.5 to about 7.5, or about 2 5 to about 6 0, or about 3 0 to about 5.0, or about 6 0 to about 1 1.0, or about 8.0 to about 10.0.
- NOFB monopropellants comprising nitrous oxide and ethylene in an oxidizer-to-fuel ratio of about 2.5 to about 1 1.0, or about 3.0 to about 9 0, or about 4.0 to about 8.0, or about 4 5 to about 7 5, or about 2.5 to about 6 0, or about 3.0 to about 5.0, or about 6.0 to about 1 1.0, or about 8 0 to about 10.0
- the ratios are chosen for specific uses.
- NOFB34 is optimized for small rocket engines (fast combustion kinetics and optimized peak lsp with frozen-at-the-throat combustion kinetics)
- NOFB37 is optimized for large rocket engines (higher density monopropellant with lsp optimized for slower combustion kinetics in larger rocket diverging exhaust nozzles)
- the NOFB monopropellants may comprise other compositions or additives up to about 50% of the monopropellant, or up to about 40% of the monopropellant, or up to about 30% of the monopropellant, or up to about 20% of the monopropellant.
- the other compositions include hydrocarbon fuels or mixtures thereof wherein the resulting monopropellant has the property that as the monopropellant is drawn down or the temperature changed, the balanced blend has minimal variation in liquid and ullage gas mixture-ratio chemistry as the liquid monopropellant boils-off to generate ullage gas under these conditions.
- the additional hydrocarbon fuels may cause a ⁇ 10% variation in rocket lsp performance due to these variations in boil-off rates for the different NOFB constituents
- the addition of small amounts of detergents, emulsifiers, or other additives may be advantageous
- Additional implementations of the technology provide NOFB monopropellants comprising nitrous oxide and two or more of acetylene, ethane or ethene in an oxidizer-to-fuel ratio of about 2 5 to about 11 0, or about 3 0 to about 9 0, or about 4 0 to about 8 0, or about 4 5 to about 7 5, or about 2 5 to about 6 0, or about 3 0 to about 5 0, or about 6 0 to about 1 1 0, or about 8 0 to about 10 0
- the monopropellant may comprise other compositions or additives up to about 50% of the monopropellant, or up to about 40% of the monopropellant, or up to about 30% of the monopropellant, or up to about 20% of the monopropellant
- the nitrous oxide is in a gas phase when mixed with the fuel during manufacturing, in other implementations the nitrous oxide is in a liquid phase when mixed with the fuel during manufacturing, and in yet other implementations, the nitrous oxide is in a mixed gas/liquid phase when mixed with the fuel during manufacturing
- the mixing is done as described in Example 1
- Figure 1 is a graph of theoretical and actual l sp performance of an NOFB monopropellant formulation
- Figure 2 illustrates the method of making the nitrous oxide fuel blends of the present invention
- Figure 3 is a chart summarizing NOFB monopropellant characteristics relative to monopropellant hydrazine and bipropellant nitro tetroxide/monomethylhydrazine
- Figure 4 is a graph illustrating storage characteristics (storage tank liquid and gas pressure and density versus temperature) for one NOFB monopropellant formulation (also known as a phase diagram)
- the NOFB monopropellant storage characteristics are also compared to pure nitrous oxide liquid and tanked hydrazine monopropellant including a typical helium pressurant load for hydrazine
- Figure 5A is an FTIR spectrum of NOFB monopropellant sampled over different tank temperatures (and comparison with the remaining gas after a % tank rapid liquid expulsion) illustrating the stability of the NOFB chemical mixture to biased constituent outgassing over extreme temperature ratios
- Figure 5B similarly shows the variation in NOFB O/F ratio in the liquid and ullage gas (gas in tank with liquid) of three NOFB blends after rapid expulsion
- the corresponding variation in l sp performance is also shown as the blend slightly vanes during a very aggressive tank liquid expulsion (80% NOFB liquid expulsion in ⁇ seconds)
- Figure 6 is a graph illustrating exemplary nozzle coefficient values for use in vacuum equivalent l sp calculations
- Figure 7A is a graph showing thermal decomposition data for one exemplary NOFB monopropellant formulation
- Figure 7B is a summary of decomposition tests vs NOFB pressure for an exemplary NOFB monopropellant
- Figure 8A is a graph illustrating the specific enthalpy of vaporization of one exemplary NOFB monopropellant relative to nitrous oxide and compared to the specific energy for heating a representative quantity of bipropellant fuel from a the same temperature to ⁇ 300°C
- Figure 8B illustrates the rapid decrease in temperature as the NOFB monopropellant is throttled or "flash-cooled" by forcing it through a pressure drop
- Figure 9 is a graph illustrating the maximum spark propagation distance for pure nitrous oxide as a function of gas pressure at the minimum nitrous oxide spark voltage of 418 V At this minimum voltage point (also known as Paschen curve minimum), for a given gap distance, both higher and lower gas pressure requires rapidly increasing spark voltages
- Figure 10 is a graph of quenching distance based on oxidizer-to-fuel ratios for one NOFB monopropellant formulation
- Figure 11 illustrates an exemplary NOFB regeneratively-cooled thruster utilizing the high volatility of the NOFB monopropellant to "flash-cool" the combustion chamber
- Figure 12 illustrates low thrust, non-optimized engine run test data in an engine utilizing an exemplary NOFB monopropellant
- Figure 13 is a graph illustrating a comparison of delivered payload mass of total wet mass rocket propulsion system performance of an exemplary NOFB monopropulsion system relative to hydrazine systems
- Figure 14 summarizes the characteristics of the NOFB deployable wing spars
- nitrous oxide fuel blend (NOFB) monopropellant comprising nitrous oxide with an organic compound, such as one or more of acetylene, ethane, or ethene resulting in a monopropellant that has a high specific impulse, low toxicity and allows for easy storage and handling in addition to other desired characteristics
- the monopropellant may be used in some implementations for rocket propulsion, working fluid production, or energy or gas generation
- the art of chemical rocket propulsion makes use of controlled release of chemically reacted or un-reacted fluids to achieve thrust in a desired direction
- the thrust acts to change a body's linear or angular momentum
- the claimed invention may be utilized in many alternative types of applications as well, including gas generation for inflation systems and inflatable deployments, in systems used to convert thermal energy in hot exhaust gases to mechanical and electrical power, and in high energy storage media for projectiles, munitions, and explosives
- Examples where the claimed technology could be applied specifically include earth-orbiting spacecraft and missile propulsion systems, launch vehicle upper stage propulsion systems and booster stages, deep space probe propulsion and power systems, deep space spacecraft ascent and earth return stages, precision-controlled spacecraft station-keeping propulsion systems, human-rated reaction control propulsion systems, spacecraft lander descent propulsion, power, and pneumatic systems for excavation (NOFB monopropellant can be used to both provide mechanical power to run drills in extraterrestrial drilling applications and to provide gases
- a monopropellant is a single fluid that typically is used for generating thrust, gas generation, and/or power (mechanical and/or electrical) generation
- Monopropellants commonly undergo exothermic chemical reactions through a catalytic, hypergohc, or spark ignition mechanism in order to release additional heat energy (commonly providing an ideally low molar mass exhaust gas as well) in order to increase mass efficiency in generating thrust and power
- Monopropellants for example, can be used in a liquid or gas rocket engine
- a common example of a monopropellant is hydrazine, often used in spacecraft propulsion for vehicle translation maneuvers (linear momentum changes) and attitude control (angular momentum changes)
- HAN hydroxyl ammonium nitrate
- Another example of a monopropellant is hydroxyl ammonium nitrate (HAN) which is currently being investigated as a lower toxicity monopropellant alternative to hydrazine
- a working fluid that has a pressure gradient between it and the surrounding environment is capable of producing mechanical work/power
- This mechanical work/power can subsequently be converted into alternative energy forms (for example, electric power generation, mechanical shaft power can be used to power an electric generator or alternator to provide electric power)
- Pressure from either the natural vapor pressure of an NOFB monopropellant and/or through NOFB monopropellant decomposition/combustion processes in combination with NOFB monopropellant-de ⁇ ved working fluids can be used strategically to produce useable work beyond simple thrust
- Example work extracting cycles that can implement the NOFB monopropellants may include, without limitation, gas turbine cycles (e g , Brayton or similar cycles), constant pressure expansions of combusted monopropellant (similar to pneumatic machines), and various piston cycle engines including but not limited to spark- ignited Otto cycles, and compression-ignited Diesel cycles
- the maximum energy that can be extracted from a chemical medium is related to its specific energy density (stored chemical energy per unit mass) As shown in Figure 3, the specific energy
- l sp specific impulse
- This metric essentially measures the amount of total impulse or imparted momentum change (integrated force over time) produced by a given propulsion system divided by the total mass of propellant consumed This result is normalized by the earth's gravitational constant (9 81 m/s 2 ) such that l sp has units of seconds regardless of what international system of units are being used (English or System Internationale (Sl) units))
- Higher l sp values indicate greater ability to impart velocity changes to vehicles for a given amount of propellant consumed
- lsp performance is similar in connotation to "miles per gallon" in a combustion-powered car engine (although one caveat here is that more engine- specific characteristics go into defining "miles per gallon" for a car as compared to rocket propulsion for a spacecraft) Because 1 ) mass is extremely expensive
- FIG. 2 demonstrates an exemplary schematic of an apparatus used to manufacture NOFB monopropellant blends Thruster performance is dependent on the propellant which is combusted For this reason it is generally important to accurately mix the monopropellant blends
- a specialized apparatus can be used to mix high vapor pressure monopropellants Essentially, the constituents can be mixed in their vapor phases and condensed in a separate container to form a high density liquid monopropellant
- the method and apparatus outlined below are for exemplary purposes, and derivations hereof may be equally acceptable manufacturing methods
- SW-# indicates a general on/off valve
- REG-# indicates a pressure reducing regulator
- IS-#s are tank isolation valves Unless otherwise noted, all valves begin closed and regulators backed completely off
- a pressure transmitter is attached to an open SW-5 valve to accurately monitor system pressure To begin manufacturing, the system is purged of air by turning the vacuum pump on, opening IS-3, IS-4, SW-6, and SW-8 Once an adequate vacuum is accomplished, SW-8 is closed Next, fuel
- Candidate fuel blends were made and tested The most promising blends were selected based on the following criteria combustion and theoretical engine performance, propellant stability, equilibrium and non-equilibrium miscibility performance, combustion limits, flame temperature, and exhaust gas chemistry for engine design, propellant phase diagram properties, and combustion reaction rates
- NOFB34 designates nitrous oxide fuel blend
- 1 is ethane
- 2 is ethylene
- 3 is acetylene
- NOFB34 is nitrous oxide blended with acetylene with an oxidizer to fuel ratio of 4
- Additional letters (a,b,c) after the oxidizer to fuel ratio number may be used to describe deviations in the blend
- an NOFB34 blend may include small amounts of specific additives to improve mixture chemistry degassing characteristics The first discovered adaptation to this blend beyond the basic nitrous oxide and fuel chemistry would therefore be denoted NOFB34a
- Figure 1 illustrates the theoretical l sp performance of a nitrous oxide/acetylene (N 2 OZC 2 H 2 ) monopropellant blend as a function of oxidizer-to-fuel (O/F) mass ratio as well as showing data from recent prototype engine test results based on measuring integrated chamber pressure and propellant mass consumed during an engine run (Additional details on the particular experimental method used for acquiring the experimental measurement are discussed in [0043] below)
- the experimentally measured l sp was acquired for an O/F ratio of 4 (errors bar based on uncertainty in actual nozzle coefficient during terrestrial testing)
- the two sets of theoretical curves (vacuum and 200/1 ) are shown for two different cases, equilibrium and frozen-at-the-throat chemical kinetics These are typical bounding scenarios for actual rocket engine performance in space applications
- the vacuum condition is from an ideal exit nozzle that is infinitely long
- the 200/1 nozzle is a more realistic diverging nozzle scenario where the exit plane area is 200 times larger than the minimum throat area of the
- a number of additional characteristics of a monopropellant are, in general, considered desirable Hydrazine has an OSHA human fatal exposure limit of approximately 50 ppm
- Low and non-toxic chemical monopropellant formulations are desired to mitigate the relatively high costs of ground handling and working with toxic monopropellant formulations
- the NOFB monopropellant formulations of the claimed invention are non-toxic and classified as asphyxiants — the NOFBs are similar to gasoline in this regard, only overexposure in very high concentrations displaces breathable air resulting in suffocation or in a more minor case can cause temporary exposure symptoms such as headaches and/or confusion In any case, the removal to a fresh air supply mitigates the symptoms to exposure
- the NOFB monopropellants rapidly volatize into air so that large concentrations of liquids are easily removed from a spill Also, where hydrazine and the bipropellant nitrotetroxide/monomethylhydrazine are corrosive and may be absorbed into the skin
- ammonia is an undesirable byproduct because of its reactions with soils that can readily complicate and contaminate sensitive soil measurements
- Tank storage characteristics of monopropellants are important for minimizing monopropellant fluid handling hardware and tank mass relative to monopropellant mass Ideally, storage densities of monopropellants are very high NOFB monopropellant densities have comparable room temperature storage tank densities as hydrazine (-0 57 g/cc) when factoring in optimized hydrazine tank designs that include internal helium reservoirs in hydrazine tanks These helium reservoirs are used for pressurizing the hydrazine to achieve reaction chamber pressures for engine and thruster operations NOFB monopropellants are self-pressurizing and do not require additional pressurant system hardware or unutilized tank volume for expelling the monopropellant While monopropellant and bipropellant hydrazine systems can typically have unutilized residual propellant in a tank that are -1-3% of the initial load, NOFB monopropellants can be expelled down to very low pressures (where they are a pure gas) such that the unutilized monopropellant is «
- Figure 4 illustrates storage characteristics of one NOFB monopropellant formulation with both monopropellant liquid and ullage gas (gas in equilibrium with liquid in tank) density and the associated monopropellant vapor pressure plotted against temperature
- Each NOFB monopropellant formulation demonstrates a unique vapor pressure and density curve
- NOFB monopropellant densities increase significantly up to ⁇ 1 g/cc at -75 0 C and freeze at ⁇ -80°C These temperatures are not uncommon for deep space and planetary surface missions that are further from the sun than earth and/or shielded from the sun (e g the Mars polar cap) While NOFB monopropellants density performance improves with lower temperature, hydrazine freezes ⁇ 0°C requiring additional heater hardware and spacecraft power to prevent freezing from occurring Compared to solid propellants (most commonly incorporating premixed solid oxidizer and fuel), NOFB monopropellants typically have higher lsp performance, and are readily throttleable ( ⁇ e can control and vary thrust output) for optimizing propellant usage in a flight trajectory, however, NOFB monopropellants tend to have lower storage densities For deep space environments, solid propellants have to be carefully handled and insulated to avoid thermal cycling and stress cracking of the propellant grains Structural flaws and minute cracks in
- Figure 5A illustrates the minimal variation in mixture chemistry for one exemplary NOFB monopropellant blend under exposed environmental conditions
- the ullage gas in the propellant tank was sampled as a function of propellant temperature (tank immersed in low temperature cold bath)
- the Fourier Transform Infrared (FTIR) Absorption Spectrum of the ullage gas was acquired as a function of different monopropellant temperatures and compared to NOFB calibration gas "fingerprints" to determine the degree of NOFB mixture alteration as a function of temperature
- FTIR Fourier Transform Infrared
- exemplary NOFB monopropellants have thermal ignition temperatures that are ⁇ 400°C ( Figure 7A and 7B) and may be as high as 650 0 C in the presence of inert materials ( ⁇ e specific grades of metals) These are very high temperature limits, and, in fact, a regeneratively- cooled (propellant cools combustion chamber) NOFB monopropellant engine has been developed and tested (discussed below and shown in Figure 1 1 ) that takes advantage of the high exemplary thermal decomposition limits of NOFB monopropellants in order to provide a desirable design mechanism for developing long life-cycle engines
- NOFB monopropellants by their nature of containment, are stored in sealed metal containers that behave as Faraday cages (prevents buildup of charge) which essentially eliminates the possibility of dry spark ignition Care in propulsion system design still must be taken with devices that could disrupt the continuous Faraday cage such as valves with insulating valve seats and plumbing interfaces, for example
- the NOFB monopropellants have been shown to have very high breakdown voltages (» 10's kV) at common terrestrial tank storage temperatures and associated pressures (in fact, N 2 O has been commonly used as a high voltage gas insulator for high voltage applications)
- the Paschen curve minimum breakdown voltage gap of N 2 O at even a very low storage pressure of -100 psia is ⁇ 0 001 mm (see Figure 9) This very small maximum gap distance is significantly smaller than the NOFB quenching
- valves impart mechanical energy into a fluid stream which could feasibly be converted into an electrical discharge through triboelect ⁇ c charging as a valve component slides across an insulting interface ( ⁇ e valve seat)
- ⁇ e valve seat an insulting interface
- thermocouple and pressure transducer were coupled into a data acquisition system and signals fed into a computer program which monitored the processed signals
- the thermocouple was an exposed tip 1/16" K type thermocouple (to reduce time lag in event detection)
- the pressure transducer was used to ensure there was not a slow leak in the system therefore reducing uncertainty in the case that an event occurred
- the flashback arrestor is utilized to isolate the main valve and the pressure transducer in the case of an event such that they are not destroyed
- the ball valve stem was electronically isolated from the rest of the system via nylon gears
- One possible failure mode could be electric charging of a valve stem causing a spark to propagate within the propellant stream Utilizing this system (and slight variations hereof), over 8,000 on/off cycles have been run without a single event recorded at pressures of IOOpsia (common feed system line pressures for valves) Flight valves are qualified in a similar experimental configuration with the range of anticipated NOFB fluid properties at the valve interface
- Figure 6 illustrates exemplary nozzle coefficient values, Cf, for use in vacuum equivalent l sp engine tests described above
- Cf nozzle coefficient values
- Figure 7A illustrates thermal decomposition data for one NOFB monopropellant formulation
- Figure 7B shows a summary of decomposition Go/NoGo test vs NOFB pressure for a different exemplary NOFB monopropellant
- This metric is of specific interest for regeneratively cooled engine designs and in defining safe temperature handling limits
- Regeneratively cooled engines use the propellant flowed through a jacket in the combustion chamber wall as a coolant to help maintain the combustion chamber walls below thermal failure limits This energy acquired during wall cooling is not lost but rather results in hotter propellant being injected back into the chamber (hence the name regenerative)
- the NOFB monopropellants While most propellants have limited cooling capacity associated with the liquid specific heat of a propellant (energy required to heat the liquid by a certain change in temperature), the NOFB monopropellants, have very high vapor pressures
- NOFB monopropellants can be forced to "flash” or vaporize and absorb substantially more energy from the combustion chamber walls by going through a phase change (liquid
- Figure 8A illustrates the large enthalpy of vaporization (energy absorbed during vaporization) of an NOFB monopropellant derived from the Phase Diagram shown in Figure 4 and compared the energy absorbed in a typical coolant that is heated from the same starting temperatures to ⁇ 300°C
- Figure 8B illustrates the rapid temperature decrease as the propellant is "Flash-cooled” started with different tank temperatures and associated tank densities and flowing the propellant through any device and/or medium that causes a pressure drop (Note quality as shown in this figure is the percent gas by mass in a liquid/gas mix in equilibrium)
- Figure 8B is also critical for evaluating feedlme propellant densities that feed an engine when considering the design of the anti-flashback systems described below, as well as temperature limits within which monopropellant feed system hardware must operate
- Figure 1 1 illustrates the successful operation of a regeneratively-cooled NOFB thruster demonstrating the principle of an NOFB flash-cooled engine This is one important feature of the NOFB monopropellants given the very
- Figure 9 illustrates exemplary Paschen curve minimum (worst case optimum pressure ⁇ gap_d ⁇ stance conditions for propagating a spark across two parallel surfaces) spark propagation distance for pure N 2 O (main NOFB constituent) as a function of gas pressure
- spark gap distances must be ⁇ 0 0001 mm
- Such small associated spark volumes are unlikely to allow inadvertent NOFB monopropellant ignition since exemplary NOFB quenching distances are at least ten times greater as discussed below and shown in Figure 10
- Monopropellants can be sensitive to shock which initiates a rapid chemical reaction ( ⁇ e detonation) resulting in catastrophic system failure Impact drop testing from 5 5 meters has shown exemplary NOFB monopropellants to be insensitive to impact-induced detonation
- liquid monopropellants comprise combined fuel and oxidizer, they can form a potential ignition mechanism (a k a "flashback") back into their storage tank Therefore, a mechanism for preventing flashback must be included in the engine and feed system design
- a very important parameter for designing an engine injector and flashback control mechanism is the quenching distance of a monopropellant This is the smallest flowpath dimension through which a flashback flame can propagate In practice this dimension is affected by additional parameters such as tortuosity (curviness of flow path) and to a lesser extent the temperature of the solid containing the flowpath.
- Figure 10 illustrates experimental data of sintered metal pore sizes sufficient for quenching an NOFB monopropellant that has been intentionally detonated to produce a flashback. These quenching distances have been incorporated into the design of an anti-flashback system using pores sizes that are equivalent or smaller than the ones that didn't allow flame propagation as shown in Figure 10.
- Propellants in general can undergo chemical reactions with storage and feed system hardware that alter the chemistry of the propellant over time.
- Preliminary long duration testing of candidate NOFB mixtures has shown them to be chemically stable in the presence of common aerospace propulsion system materials (e.g. stainless steel, Teflon).
- common aerospace propulsion system materials e.g. stainless steel, Teflon.
- three different monopropellant blends were exposed to Teflon and stainless steel and allowed to sit for 1.5 years at room temperature. No chemical alteration of the NOFB monopropellant has been observed as indicated by Fourier Transform InfraRed (FTIR) absorption spectroscopy.
- FTIR Fourier Transform InfraRed
- Figure 12 illustrates exemplary low thrust, non-optimized engine run test data in an engine utilizing a NOFB (nitrous oxide fuel blend) monopropellant. This figure is included to demonstrate successful thruster performance utilizing NOFB monopropellant blends in a flight-like configuration. Thrust was calculated based on nozzle coefficients for vacuum equivalent expansion and engine pressures.
- NOFB nitrogen oxide fuel blend
- Figure 13 illustrates a comparison of delivered payload mass (minus tankage) to total wet mass (fueled vehicle) versus imparted vehicle velocity change for example NOFB monopropulsion systems relative to a hydrazine system assuming different tankage (percentage of rocket propulsion dry mass relative to total propulsion system mass) as a function of required spacecraft changes in velocity.
- Example 4
- a small 4 cylinder engine (160cc) was modified for use with the NOFB monopropellants of the present invention to test the concept of using the NOFB monopropellant for operating extremely high altitude military aircraft engines and power supplies for launch vehicles and manned spacecraft applications (NASA's Apollo 13 mission was almost lost because of the lack of a back-up power supply that could have operated from the onboard rocket propellant)
- NSA's Apollo 13 mission was almost lost because of the lack of a back-up power supply that could have operated from the onboard rocket propellant
- the engine was tested with the nitrous oxide rocket fuel blends of the present invention comprising either ethylene or acetylene While the engine hardware associated with these applications is different from the rocket engine hardware identified, the NOFB monopropellants are still fundamentally the same as the rocket monopropellants and the same advantages previously identified in combustion performance, non-toxicity, fluid-handling characteristics, and rapid combustion kinetics relative to hydrazine, for example, apply Hydrazine-based engines exist for alternative applications, but, similar to the rocket application, a major limitation to widespread use of hydrazine in these applications relative to NOFB monopropellants is the much lower energy density and toxicity of hydrazine
- the monopropellants of the present invention can be used in deployment system architecture This is particularly beneficial when an overall NOFB monopropulsion system is already required for applications associated with the deployment application
- the present invention has also been studied for use in an inflatable/rigidizable pressurized propeller, for a wing spar and sustaining wing gas pressure, and for an inflatable/rigidizable rover wheel.
- the basic system uses the liquid to combustible gas generator for rapid deployment, and a sustaining gas-pressure for robust long term deployment of wings and/or deployables
- the exemplary lightweight ⁇ gidizable wheel is designed to provide a wheel sized at about 1 5 meters, for less than 1 hazard per 100m in aggressive 25% rock abundant Mars terrains and ability to navigate with 30 cm/pixel orbital resolution Further, the wheel supports more than 100kg per ⁇ 10kg wheel
- the wheel employs a set of inflatable shells and has a composite rim
- the exemplary wing spars utilize the monopropellants of the present invention with an inflatable/rapid ⁇ gidizing wing spar (combustion/flash-cool) for providing relatively stiff wing to maintain stable C L and C D across wing to achieve high overall L/D
- an inflatable/rapid ⁇ gidizing wing spar combustion/flash-cool
- the monopropellants of the present invention are also used in deployment systems to provide inflatable/ ⁇ gidizable propellers
- the deployables of the present invention may also contain an annihilation mechanism for post-operational life This contingency option can be used for deployment deep behind enemy lines where recovery may not be an option
- NOFB rocket monopropellant used initially for propulsive applications is also used to operate these additional auxiliary deployment and operational modes
Abstract
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Priority Applications (4)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
JP2010533326A JP5711536B2 (en) | 2007-11-09 | 2008-11-10 | Monopropellant made by mixing dinitrogen monoxide and fuel |
AU2008323666A AU2008323666A1 (en) | 2007-11-09 | 2008-11-10 | Nitrous oxide fuel blend monopropellants |
CN200880115398A CN101855325A (en) | 2007-11-09 | 2008-11-10 | Nitrous oxide fuel blend monopropellants |
EP08848086.8A EP2209876A4 (en) | 2007-11-09 | 2008-11-10 | Nitrous oxide fuel blend monopropellants |
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US98699107P | 2007-11-09 | 2007-11-09 | |
US60/986,991 | 2007-11-09 |
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PCT/US2008/083039 WO2009062183A1 (en) | 2007-11-09 | 2008-11-10 | Nitrous oxide fuel blend monopropellants |
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US (1) | US20090133788A1 (en) |
EP (1) | EP2209876A4 (en) |
JP (1) | JP5711536B2 (en) |
CN (1) | CN101855325A (en) |
AU (1) | AU2008323666A1 (en) |
WO (1) | WO2009062183A1 (en) |
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EP2620422A1 (en) | 2012-01-27 | 2013-07-31 | Centre National D'etudes Spatiales | N2O-based, ionic monopropellants for space propulsion |
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CN104035333B (en) * | 2014-05-23 | 2015-06-10 | 北京空间飞行器总体设计部 | Optimization method for powered lowering initial key parameters of deep space probe |
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- 2008-11-10 AU AU2008323666A patent/AU2008323666A1/en not_active Abandoned
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Also Published As
Publication number | Publication date |
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JP2011502935A (en) | 2011-01-27 |
EP2209876A4 (en) | 2014-01-08 |
JP5711536B2 (en) | 2015-05-07 |
US20090133788A1 (en) | 2009-05-28 |
EP2209876A1 (en) | 2010-07-28 |
AU2008323666A1 (en) | 2009-05-14 |
CN101855325A (en) | 2010-10-06 |
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