USRE37853E1 - Fast quench reactor and method - Google Patents
Fast quench reactor and method Download PDFInfo
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- USRE37853E1 USRE37853E1 US09/569,146 US56914600A USRE37853E US RE37853 E1 USRE37853 E1 US RE37853E1 US 56914600 A US56914600 A US 56914600A US RE37853 E USRE37853 E US RE37853E
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Definitions
- This disclosure pertains to equipment for thermal conversion of reactants to desired end products, which might be either a gas or ultrafine solid particles. It also relates specifically to methods for effectively producing such end products.
- the present rector and method are intended for high temperature reactions that require rapid cooling to freeze the reaction products to prevent back reactions or decompositions to undesirable products. They use adiabatic and isentropic expansion of gases in a converging-diverging nozzle for rapid quenching. This expansion can result in cooling rates exceeding 10 10 K/s, thus preserving reaction products that are in equilibrium only at high temperatures.
- the large scale production processes used in the titanium industry have been relatively unchanged for many years. They involve the following essential steps: (1) Chlorination of impure oxide ore, (2) purification of TiCl 4 (3) reduction by sodium or magnesium to produce titanium sponge, (4) removal of sponge, and (5) leaching, distillation and vacuum remelting to remove Cl, Na, and Mg impurities.
- powder metallurgy for near net shape fabrication. For instance, it has been estimated that for every kilogram of titanium presently utilized in an aircraft, 8 kilograms of scrap are created. Powder metallurgy can substantially improve this ratio. Although this technology essentially involves the simple steps of powder production followed by compaction into a solid article, considerable development is currently underway to optimize the process such that the final product possesses at least equal properties and lower cost than wrought or cast material.
- titanium alloy parts One potential powder metallurgy route to titanium alloy parts involves direct blending of elemental metal powders before compaction.
- titanium sponge fines from the Kroll process are used, but a major drawback is their high residual impurity content (principally chlorides), which results in porosity in the final material.
- the other powder metallurgy alternative involves direct use of titanium alloy powder subjected to hot isostatic pressing.
- the present disclosure is the result of research to develop a new plasma process for direct and continuous production of high purity titanium powder and/or ingot.
- steps (1) and (2) of the Kroll or Hunter processes are retained in this process, but steps (3), (4), and (5) are replaced by a single, high temperature process.
- This new process can directly produce high purity titanium from TiCl 4 and eliminates the need for subsequent purification steps.
- the resulting titanium product can be either a powder suitable for the elemental blend approach to powder metallurgy or in an ingot or sponge-substitute. Titanium alloy powders and other materials can also be produced in a single step process by such direct plasma production systems.
- the titanium vapor product is then either condensed to liquid in a water-cooled steel condenser at about 3000 K, from which it overflows into a mold, or is flash-cooled by hydrogen to powder, which is collected in a bin. Since the liquid titanium was condensed from gas with only gaseous by-products or impurities, its purity, except for hydrogen, was expected to be high.
- Natural gas where methane is the main hydrocarbon
- U.S. Natural gas
- Huge reserves of natural gas are known to exist in remote areas of the continental U.S., but this energy resource cannot be transported economically and safely from those regions. Conversion of natural gas to higher value hydrocarbons has been researched for decades with limited success in today's economy.
- Acetylene can be used as a feed stock for plastic manufacture or for conversion by demonstrated catalyzed reactions to liquid hydrocarbon fuels.
- the versatility of C 2 H 2 as a starting raw material is well known and recognized.
- Current feed stocks for plastics are derived from petro-chemical based raw materials. Supplied from domestic and foreign oil reserves to produce these petrochemical based raw materials are declining, which puts pressure on the search for alternatives to the petrochemical based feed stock. Therefore, the interest in acetylene based feed stock has currently been rejuvenated.
- Thermal conversion of methane to liquid hydrocarbons involves indirect or direct processes.
- the conventional methanol-to-gasoline (MTG) and the Fischer-Tropsch (FT) processes are two prime examples of such indirect conversion processes which involve reforming methane to synthesis gas before converting to the final products. These costly endothermic processes are operated at high temperatures and high pressures.
- Light olefins can be formed by very high temperature (>1800° C.) abstraction of hydrogen from methane, followed by coupling of hydrocarbon radicals.
- High temperature conversion of methane to acetylene by the reaction 2CH 4 ⁇ C 2 H 2 +3H 2 is an example. Such processes have existed for a long time.
- Methane to acetylene conversion processes currently use cold liquid hydrocarbon quenchants to prevent back reactions. Perhaps the best known of these is the Huels process which has been in commercial use in Germany for many years.
- the electric arc reactor of Huels transfers electrical energy by ‘direct’ contact between the high-temperature arc (15000-20000 K) and the methane feed stock.
- the product gas is quenched with water and liquefied propane to prevent back reactions.
- Single pass yields of acetylene are less than 40% for the Huels process.
- Overall C 2 H 2 yields are increased to 58% by recycling all of the hydrocarbons except acetylene and ethylene.
- Westinghouse has employed a hydrogen plasma reactor for the cracking of natural gas to produce acetylene.
- hydrogen is fed into the arc zone and heated to a plasma state.
- the exiting stream of hot H 2 plasma at temperatures above 5000 K is mixed rapidly with the natural gas below the arc zone, and the electrical energy is indirectly transferred to the feed stock.
- the hot product gas is quenched with liquefied propane and water, as in the Huel process, to prevent back reactions.
- separation of the product gas from quench gas is needed. Recycling all of the hydrocarbons except acetylene and ethylene has reportedly increased the overall yield to 67%.
- the H 2 plasma process for natural gas conversion has been extensively tested on a bench scale, but further development and demonstration on a pilot scale is required.
- the Scientific and Industrial Research Foundation (SINTEF) of Norway has developed a reactor consisting of concentric, resistance-heated graphite tubes. Reaction cracking of the methane occurs in the narrow annular space between the tubes where the temperature is 1900 to 2100 K. In operation, carbon formation in the annulus led to significant operational problems. Again, liquefied quenchant is used to quench the reaction products and prevent back reactions. As with the previous two acetylene production processes described above, separation of the product gas from quench gas is needed. The overall multiple-pass acetylene yield from the resistance-heated reactor is about 80% and the process has been tested to pilot plant levels.
- the present fast quench reactor can use an electric arc plasma process to crack the methane, but it requires no quenchant to prevent back reactions. In this manner it eliminates any need for extensive separation.
- This invention relates to a reactor and method for producing desired end products by injecting reactants into the inlet end of a reactor chamber; rapidly heating the reactants to produce a hot reactant stream which flows toward the outlet end of the reactant chamber, the reactor chamber having a predetermined length sufficient to effect heating of the reactant stream to a selected equilibrium temperature at which the desired end product is available within the reactant stream as a thermodynamically stable reaction product at a location adjacent to the outlet end of the reaction chamber; passing the gaseous stream through a restrictive convergent-divergent nozzle arranged coaxially within the remaining end of the reactor chamber to rapidly cool the gaseous stream by converting thermal energy to kinetic energy as a result of adiabatic and isentropic expansion as it flows axially through the nozzle and minimizing back reactions, thereby retaining the desired end product within the flowing gaseous stream; and subsequently cooling and slowing the velocity of the desired end product and remaining gaseous stream exiting from the nozzle.
- the rapid heating step is accomplished by introducing a stream of
- FIG. 1 is a schematic cross-sectional view of a reactor system
- FIG. 2 is an enlarged cross-sectional view of the reactor chamber and converging-diverging nozzle;
- FIG. 3 is a plot of temperatures, pressures, specific volumes and nozzle throat areas as a function of gas velocity in the reactor apparatus
- FIG. 4 is a graph plotting equilibrium concentrations in a titanium tetrachloride and hydrogen system as a function of temperature
- FIG. 5 is a graph plotting equilibrium concentrations in a titanium tetrachloride and hydrogen system with added argon gas as a function of temperature
- FIG. 6 is a graph plotting equilibrium concentrations in a methane decomposition system with solid carbon precipitation.
- FIG. 7 is a graph plotting equilibrium concentrations in a methane decomposition system with solid carbon precipitation prevented.
- the fast quench reactor and method of operation described in this disclosure take advantage of the high temperatures (5,000° to 20,000° C.) available in a high temperature heating means such as a thermal plasma to produce materials that are thermodynamically stable at these high temperatures. These materials include metals, alloys, intermetallics, composites, gases and ceramics.
- a converging-diverging (De Laval) nozzle located downstream from the plasma and reactant addition inlet(s) produces a rapid drop in kinetic temperature in a flowing gas stream. This effectively “freezes” or stops all chemical reactions. It permits efficient collection of desired end products as the gases are rapidly cooled without achieving an equilibrium condition. Resulting end products which have been produced in the plasma at high temperature but are thermodynamically unstable or unavailable at lower temperatures can then be collected due to resulting phase changes (gas to solid) or stabilization by cooling to a lower equilibrium state (gas to gas).
- the fast quench reactor and method of this invention shall be described and illustrated forthwith in terms of a rapid heating means comprising a plasma torch and a stream of plasma arc gas.
- the rapid heating means can also include other rapid heating means such as lasers, and flames produced by oxidation of a suitable fuel, e.g. an oxygen/hydrogen flame.
- FIG. 12 A schematic diagram of an ultra fast quenching apparatus is shown in FIG. 12 .
- An enclosed axial reactor chamber 20 includes an inlet at one end (shown to the left) and an outlet at its remaining end (shown to the right).
- a plasma torch 21 is positioned adjacent to the reactor chamber. Torch 21 is used to thermally decompose an incoming gaseous stream within a resulting plasma 29 as the gaseous stream is delivered through the inlet of the reactor chamber 20 .
- a plasma is a high temperature luminous gas which is at least partially (1 to 100%) ionized.
- a plasma is made up of gas atoms, gas ions, and electrons. In the bulk phase a plasma is electrically neutral.
- a thermal plasma can be created by passing a gas through an electric arc. The electric arc will rapidly heat the gas by resistive and radiative heating to very high temperatures within microseconds of passing through the arc.
- the plasma is typically luminous at temperatures above 9000 K.
- a plasma can be produced with any gas in this manner. This gives excellent control over chemical reactions in the plasma as the gas might be neutral (argon, helium, neon), reductive (hydrogen, methane, ammonia, carbon monoxide) or oxidative (oxygen, nitrogen, carbon dioxide). Oxygen or oxygen/argon gas mixtures are used to produce metal oxide ceramics and composites. Other nitride, boride, and carbide ceramic materials require gases such as nitrogen ammonia, hydrogen, methane, or carbon monoxide to achieve the correct chemical environment for synthesis of these materials.
- An incoming stream of plasma gas is denoted by arrow 31 .
- the plasma gas can also be a reactant or can be inert.
- a gaseous stream of one or more reactants (arrow 30 ) is normally injected separately into the plasma 29 , which is directed toward the downstream outlet of the reactor chamber 20 .
- the gaseous stream moving axially through the reactor chamber 20 includes the reactants injected into the plasma arc or within a carrier gas.
- Reactant materials are usually injected downstream of the location where the arc attaches to the annular anode of the plasma generator or torch.
- Materials which can be injected into the arc region include natural gas, such as is used in the Huels process for the production of ethylene and acetylene from natural gas.
- Gases and liquids are the preferred forms of injected reactants. Solids may be injected, but usually vaporize too slowly for chemical reactions to occur in the rapidly flowing plasma gas before the gas cools. If solids are used as reactants, they will usually be heated to a gaseous or liquid state before injection into the plasma.
- a convergent-divergent nozzle 22 is coaxially positioned within the outlet of the reactor chamber 20 .
- the converging or upstream section of the nozzle restricts gas passage and controls the residence time of the hot gaseous stream within the reactor chamber 20 , allowing its contents to reach thermodynamic equilibrium.
- the contraction that occurs in the cross sectional size of the gaseous stream as it passes through the converging portions of nozzle 22 change the motion of the gas molecules from random directions, including rotational and vibrational motions, to straight line motion parallel to the reactor chamber axis.
- the dimensions of the reactor chamber 20 and the incoming gaseous flow rates are selected to achieve sonic velocity within the restricted nozzle throat.
- the confined stream of gas enters the diverging or downstream portions of the nozzle 22 , it is subjected to an ultra fast decrease in pressure as a result of a gradual increase in volume along the conical walls of the nozzle exit.
- the resulting pressure change instantaneously lowers the temperature of the gaseous stream to a new equilibrium condition.
- An additional reactant such as hydrogen at ambient temperatures, can be tangentially injected into the diverging section of nozzle 22 (arrow 32 ) to complete the reactions or prevent back reactions as the gases are cooled.
- Supply inlets for the additional reactant gas are shown in FIG. 1 at 23 .
- Numerals 24 and 25 designate a coolant inlet and outlet for the double-walled structure of the reactor chamber 20 . Coolant flow is indicated by arrows 33 and 34 .
- the walls of nozzle 22 and a coaxial cool down chamber 26 downstream from it should also be physically cooled to minimize reactions along their inner wall surfaces.
- Reaction particles are collectable within a cyclone separator shown generally at 27 .
- a downstream liquid trap 28 such as a liquid nitrogen trap, can be used to condense and collect reactor products such as hydrogen chloride and ultra-fine powders within the gaseous stream prior to the gaseous stream entering a vacuum pump 29 .
- FIG. 2 further illustrates details of the converging-diverging nozzle structure.
- the same reference numerals are used in FIG. 2 as in FIG. 1 .
- the reactor chamber 20 can be operated at atmospheric pressure or in a pressurized condition, while the chamber 26 downstream from nozzle 22 is maintained at a vacuum pressure by operation of pump 29 .
- the sudden pressure change that occurs as the gaseous stream traverses nozzle 22 brings the gaseous stream to a lower equilibrium condition instantly and prevents unwanted back reactions that would occur and more drawn out cooling conditions.
- Typical residence times for materials within the free flowing plasma are on the order of milliseconds.
- the reactants liquid or gas
- the injected stream of reactants is injected normal (90° angle) to the flow of the plasma gases. In some cases positive or negative deviations from this 90° angle by as much as 30° may be optimum.
- the high temperature of the plasma rapidly vaporizes the injected liquid materials and breaks apart gaseous molecular species to their atomic constituents.
- metals titanium, vanadium, antimony, silicon, aluminum, uranium, tungsten
- metal alloys titanium/vanadium, titanium/aluminum, titanium/aluminum/vanadium
- intermetallics nickel aluminide, titanium aluminide
- ceramics metal oxides, nitrides, borides, and carbides
- metal halides chlorides, bromides, iodides, and fluorides
- Solid metal halide materials are preferably vaporized and injected into the plasma as a liquid or gas
- the reaction chamber 20 is the location in which the preferred chemical reactions occur. It begins downstream from the plasma arc inlet and terminates at the nozzle throat. It includes the reactor areas in which reactant injection/mixing and product formation occurs, as well as the converging section of the quench nozzle.
- Temperature requirements within the reactor chamber and its dimensional geometry are specific to the temperature required to achieve an equilibrium state with an enriched quantity of each desired end product.
- the reactions chamber is an area of intense heat and chemical activity it is necessary to construct the reactor chamber of materials that are compatible with the temperature and chemical activity to minimize chemical corrosion from the reactants, and to minimize melting degradation and ablation from the resulting intense plasma radiation.
- the reactor chamber is usually constructed of water cooled stainless steel, nickel, titanium, or other suitable materials.
- the rector chamber can also be constructed of ceramic materials to withstand the vigorous chemical and thermal environment.
- the reaction chamber walls are internally heated by a combination of radiation, convection and conduction. Cooling of the reaction chamber walls prevents unwanted melting and/or corrosion at their surfaces.
- the system used to control such cooling should maintain the walls at as high a temperature as can be permitted by the selected wall material, which must be inert to the reactants within the reactor chamber at the expected wall temperatures. This is true also with regard to the nozzle walls, which are subjected to heat only by convection and conduction.
- the dimensions of the reactor chamber are chosen to minimize recirculation of the plasma and reactant gases and to maintain sufficient heat (enthalpy) going into the nozzle throat to prevent degradation (undesirable back or side reaction chemistry).
- the length of the reactor chamber must be determined experimentally by first using an elongated tube within which the user can locate the target reaction threshold temperature.
- the reactor chamber can then be designed long enough so that reactants have sufficient residence time at the high reaction temperature to reach an equilibrium state and complete the formation of the desired end products.
- Such reaction temperatures can range from a minimum of about 1700° C. to about 4000° C.
- the inside diameter of the reactor chamber 20 is determined by the fluid properties of the plasma and moving gaseous stream It must be sufficiently great to permit necessary gaseous flow, but not so large that desirable recirculating eddys or stagnant zones are formed along the walls of the chamber. Such detrimental flow patterns will cool the gases prematurely and precipitate unwanted products, such as subchlorides or carbon. As a general rule, the inside diameter of the reactor chamber 20 should be in the range of 100 to 150% of the plasma diameter at the inlet end of the reactor chamber.
- the purpose of the converging section of the nozzle is to compress the hot gases rapidly into a restrictive nozzle throat with a minimum of heat loss to the walls while maintaining laminar flow and a minimum of turbulence. This requires a high aspect ratio change in diameter that maintains smooth transitions to a first steep angle (>45°) and then to lesser angles (>45°) leading into the nozzle throat.
- the purpose of the nozzle throat is to compress the gases and achieve sonic velocities in the flowing hot gaseous stream. This converts the random energy content of the hot gases to translational energy (velocity) in the axial direction of gas flow. This effectively lowers the kinetic temperature of the gases and almost instantaneously limits further chemical reactions.
- the velocities achieved in the nozzle throat and in the downstream diverging section of the nozzle are controlled by the pressure differential between the reactor chamber and the section downstream of the diverging section of the nozzle. Negative pressure can be applied downstream or positive pressure applied upstream for this purpose.
- the purpose of the diverging section of the nozzle is to smoothly accelerate and expand gases exiting the nozzle from sonic to supersonic velocities, which further lowers the kinetic temperature of the gases.
- smooth acceleration in practice requires use of a small diverging angle of less than 35 degrees to expand the gases without suffering deleterious effects of separation from the converging wall and inducing turbulence. Separation of the expanding gases from the diverging wall causes recirculation of some portion of the gases between the wall and the gas jet exiting the nozzle throat. This recirculation in turn results in local reheating of the expanding gases and undesirable degradation reactions, producing lower yields of desired end products.
- the super fast quench phenomena phenomenon observed in this reactor is achieved by rapidly converting thermal energy in the gases to kinetic energy via a modified adiabatic and isentropic expansion through a converging-diverging nozzle.
- the gas temperature and pressure drop extremely fast and the gas reaches supersonic velocity. It is important to first raise the temperature of the reactants in the rector chamber to a level at which the desired end product is more stable than other reaction products in equilibrium with it. This is normally a consequence of the fact that the free energy of the desired end product will decrease at the selected elevated temperatures in comparison to the remaining reaction products.
- this window of opportunity is very short-lived (>10 ⁇ 3 sec) in a high temperature reactor.
- the reactor nozzle 22 (FIG. 2) can be divided into three sections: the convergent reaction chamber 10 , the nozzle throat 11 , and the divergent quench chamber 12
- the entrance angle to the throat area, the cross-sectional area of the throat, and the diverging angle after the throat all exert influence on the temperature, pressure, and velocity profiles of the plasma gas.
- the gas In the converging-diverging nozzle, the gas is flowing from a higher pressure P 0 to a lower pressure P 1 . During passage of the gas through the nozzle, there will be a rapid transformation of thermal energy to kinetic energy. This kinetic energy will give rise to a high gas velocity after discharging from the nozzle. The gas enters the converging section at a low velocity and will emerge at the diverging section with a higher velocity.
- P 0 , P 1 , T 0 , and T 1 are initial and final pressures and temperatures of the gas, respectively
- ⁇ is the ratio of C r /C v where C p and C v are the heat capacaties at contgsant pressure and volume, respectively.
- ⁇ is 1.66 for Ar, 1.30 for H 2 , and 1.11 for C 2 H 2 .
- This equation can be used to estimate the temperature drop across the nozzle throat if the initial and final pressures of the gases are known or vice versa.
- the mass flow rate, m is related to the cross-sectional area (A*) of the nozzle throat, the velocity (V) and the specific volume ( ⁇ ) of the gas at the throat.
- the specific volume ( ⁇ ) is the inverse of gas density at the cross section.
- A* is the cross-sectional area at the throat of the nozzle, and A is the cross-sectional area of the converging-diverging section.
- the preferred method for producing titanium from titanium tetrachloride involves directing titanium tetrachloride vapor and a hydrogen into a hot plasma torch operated at 12 kW with a mixture of argon and hydrogen as the plasma gas (95% Argon; 5% Hydrogen, by volume) to decompose it to titanium and chlorine, followed by rapid expansion of the resulting hot gases and cooling with additional hydrogen to retain the titanium in an elemental solid metal state.
- the diameter and length (6.0 mm ⁇ 700.0 mm) of the reaction chamber was chosen to obtain maximum mixing while maintaining a minimum of 4000 K temperature at the entrance of the nozzle throat.
- the reaction chamber, converging/diverging nozzle were constructed from nickel 200 alloy to reduce corrosion. Standard equations were used to calculate the dimensions of the bell-shaped converging nozzle, nozzle throat diameter diverging angle, and diverging nozzle exit diameter.
- Plasma Torch 10 kW laboratory plasma torch
- Plasma Gas 95% Argon, 5% Hydrogen. Average total gas flow was maintained at 23.6 liters/min.
- Reactant Injection Gaseous (200° C.) Titanium tetrachloride at the point where the plasma plume exits the plasma torch.
- the hot titanium tetrachloride injection tubes, reaction chamber and converging/diverging nozzle section were constructed from nickel 200 alloy to minimize corrosion.
- Injection Rate Vaporized Titanium tetrachloride was injected at the rate of 10.0 to 15.0 milliliters/hour. This resulted in a titanium metal powder production rate of 5 grams per hour.
- Reaction Chamber Water-cooled Nickel 200 cylinder 6.0 mm ⁇ 20.0 mm
- Nozzle throat 2.0 mm ⁇ 1.0 mm in length, determined from standard equations.
- Diverging Nozzle Conical shaped with 14° included angle expanding out to a 12.0 mm diameter.
- Cool down section Water-cooled stainless steel, 12.0 mm diameter ⁇ 600.0 mm
- Cyclone collectors Water-cooled stainless steel, 12.0 mm inlet and outlet diameter, 50.0 mm inside diameter body, designed to maintain high entrance and exit velocity
- Off-Gas Cleanup After product collection the process gas was passed through a liquid nitrogen cold trap and HEPA filter to remove HCl gas and residual titanium particles before the gas enter the mechanical vacuum pump.
- Vacuum System A mechanical vacuum pump was used to maintain pressure downstream from the nozzle throat at 5.0 to 10.0 Tort (mm Hg)
- FIGS. 1 and 2 of the drawings pertain to an apparatus tested for recovering elemental metals from metal-containing compounds.
- the elemental metal is titanium and the metal-containing compound is titanium tetrachloride (TiCL 4 ).
- TiCL 4 titanium tetrachloride
- the illustrated apparatus is suitable for use with other metals and compounds where plasma processing of the compound requires ultra fast quenching to prevent back reactions.
- the plasma torch 21 located at the reactor chamber inlet thermally decomposes an incoming gaseous stream comprised of a metal-containing compound plus one or more reactants as the resulting gaseous stream moves axially through the reactor chamber 20 in conjunction with a carrier gas.
- the resulting hot gaseous stream is then directed through the coaxial convergent-divergent nozzle 22 .
- the convergent portion 10 of the nozzle 22 controls the residence time of the hot gaseous stream within the reactor chamber 20 , thereby allowing its contents to reach thermodynamic equilibrium. It also streamlines the flow of hot gases, converting their motion from random movement to straight line movement along the central nozzle axis.
- the divergent portion 12 of the nozzle 22 subjects the stream to an ultra fast decrease in pressure.
- Quenching streams of gas are introduced into the hot gaseous stream through inlets 23 as it passes through the nozzle. This rapidly cools the contents of the hot gaseous stream at a rate that condenses the elemental metal and inhibits formation of equilibrium products.
- the plasma reduction is based on a quasi equilibrium-temperature quench sequence in which the initiation of nucleation is controlled by passage of a heated gaseous stream through a converging-diverging nozzle geometry. Results from present system tests have shown the feasibility of the process.
- the powder product is extremely fine ( ⁇ 20 nm).
- FIG. 4 shows the species as a function of temperature for a TiCl 4 +2H 2 system at 1 atm.
- argon taken into account (to 96%) there is basically no change in the relative species distribution.
- FIG. 4 shows the chlorides as stripped off, until at temperatures above 5000 K there is a substantial amount of only Ti, Ti + , Cl, Cl ⁇ , TiCl, HCl and H 2 .
- the amount of hydrogen, relative to that required for a stoichiometric HCl product is increased to 32:1 this diagram shifts to lower temperatures (FIG. 5 ). In all cases the requirement is for good mixing and a sufficient residence time of the reactants in the plasma.
- homogeneous nucleation of particles from the vapor in a plasma system has been studied theoretically and published discussion of such issues are readily available.
- the initiation of homogeneous nucleation depends on the formation of small atom clusters which arise due to collisions. Normally, the cluster evaporation rate is much greater than the condensation rate and the particle clusters do not grow. However at sufficiently low temperatures the vapor becomes supersaturated and the condensation rate drastically increases. This results in a nucleation burst after which time the particles increase in size slowly.
- the saturation vapor pressures of Ti—Cl compounds at all temperatures are greater than that of Ti, and it is possible to selectively condense Ti metal.
- the presence of hydrogen serves to isolate the titanium from the chlorine atoms by forming both HCl and TiH In the gas phase.
- the converging-diverging nozzle configuration used in supersonic flow applications offers possibilities to control both the temperature quench rate and the concentration at which the plasma becomes “frozen” during the expansion.
- the converging-diverging DeLaval nozzle and the associated Prandtl-Meyer expansion process are discussed in standard texts on compressible fluid flow. In such expansion nozzles the hot plasma gas undergoes an approximate isentropic expansion and the energy in the gas (its enthalpy) is converted to unidirectional velocity in the diverging nozzle. When the exit pressure is sufficiently low. It is possible to reach supersonic speeds. Non-adiabatic expansion processes which are attained in practice aid in the resultant temperature search.
- Nitrogen gas impurities in such systems result in the formation of solid NH 4 Cl powder which can be separated from the (black) powder produced by heat treating at about 400° C., in flowing hydrogen. Oxygen impurities, however, result in TiO 2 production. In virtually all runs to date, the only chlorine in the final product is that tied up as ammonium chloride and the product can be upgraded to be chlorine free. Presently HCl is condensed in a cold trap placed just before the downstream pumping system
- the powder produced is black.
- the as-produced product has been analyzed by SEM and characterized by Energy Dispersion Spectra (EDS).
- EDS Energy Dispersion Spectra
- a SEM scan of the powder showed finer structure.
- a typical x-ray diffraction (XRD) scan is featureless (flat). It shows no crystal structure nor any short range ordering.
- An electron diffraction pattern confirms this result.
- the maximum yield of titanium metal to date with the present system is 5 gm/tr. It is 100% free of chlorine.
- TiO 2 production in the 50 nm range can also be carried out in the existing facilities.
- TiCl 4 is injected into an argon plasma and mixed with O 2 just before the quench zone.
- Most of the TiO 2 produced today is used in the paint industry and a 50 nm size (rather than the present 200 nm) is advantageous.
- Titanium dioxide particles can be produced with average diameters of 10 nanometers or less in the narrow size ranges as defined, which can find use as a sun blocking agent for protecting human skin against harmful effects of sunlight.
- the process meets all requirements for titanium production, in that it provides downstream reduction in a kinetically controlled reactor to remove halide from back reactions, leaving free metal in the exiting gaseous stream Unwanted atomic reactions cannot occur in the reactor due to the short residence time of the gaseous stream.
- Methane conversion to acetylene in a high temperature reactor follows the theoretical chemical reaction: 2CH 4 ⁇ C 2 H 2 +3H 2 .
- the main by-product is hydrogen, instead of tars and acetylene black.
- Such studies also showed that pyrolysis in the presence of hydrogen suppressed carbon formation.
- FIGS. 6 and 7 respectively show the equilibrium compositions of methane conversion to acetylene with (FIG. 6) and without (FIG. 7) solid carbon nucleation in the reaction. It is clearly seen from these results that if C 2 H 2 is allowed to ‘slowly’ reach equilibrium at low temperatures it will decompose to acetylene black. Therefore, to maximize acetylene formation, the nucleation of solid carbon from acetylene must be suppressed at all temperatures.
- ⁇ is surface tension
- P i is the vapor pressure of species i
- v is the molecular volume of species i.
- SS a ratio of P/P ⁇ is the supersaturation of species i with its solid at temperature T.
- T is the degree of supersaturation of the vapor pressure of species i at the specific temperature T.
- the homogeneous nucleation of carbon solid from the supersaturated hydrocarbon vapor species i occurs by the following sequence of events:
- the nucleation occurs like a burst over a relatively short time period (10 ⁇ 6 s).
- the nucleation terminates due to the loss of nucleating species in the gas phase which are depleted by diffusion to the freshly formed particles.
- the super fast quench phenomena observed in this reactor is achieved by rapidly converting thermal energy in the gases to kinetic energy via a modified adiabatic and isentropic expansion through a converging-diverging nozzle.
- the gas temperature and pressure drop extremely fast and the gas reaches supersonic velocity.
- Acetylene is more stable than other alkanes or alkenes at temperatures above 2000 K. This is a consequence of the fact that the free energy of acetylene decreases at elevated temperatures compared to other hydrocarbons.
- the average temperature should be between 2500 to 2000 K after CH 4 injection, followed by quenching the gas composition immediately to ⁇ 500 K to stabilize the acetylene.
- Locating the proper temperature zone for maximum C 2 H 2 formation before quenching is important to minimize solid carbon nucleation.
- the plasma temperature is very high (>>5000 K) and the plasma gas is very viscous. This temperature will need to be cooled to an average of 2500-2000 K by mixing with injected methane for maximum acetylene yield. To achieve good mixing between methane and plasma gas to reach a uniform average reaction temperature it is necessary to overcome the high viscosity of the plasma gas.
- the window of opportunity for stabilizing maximum acetylene yield is very narrow and short. Therefore, defining the location of methane injection and position of the nozzle for immediate quenching of the product is extremely important.
- a Plasma Fast Quench Reactor was designed and built, utilizing expansive cooling to convert methane to acetylene. It was constructed basically as shown in FIGS. 1 and 2.
- Hydrogen was used as a reactive plasma gas to heat methane to reaction temperatures and also served as a suppressant for solid carbon nucleation from the reaction. Downstream in the nozzle region, hydrogen could be used as an optional coolant of the diverging section of the nozzle if it is desirable.
- Initial experiments of methane conversion based on carbon balances yielded a product, in a single pass, consisting of 71% acetylene, 27% carbon black and 2% ethylene.
- the product gas also contained hydrogen as a by-product.
- the process has a very high selectivity to acetylene production.
- the converging-diverging nozzle converted thermal energy to kinetic energy. Gas velocity downstream from the nozzle was believed to be supersonic; opportunities to use this kinetic energy to drive a turbine-generator are obvious.
- By-product hydrogen could be used as feed stock for other processes or could be burned to drive a turbine generator to provide additional electrical power to the process.
- the acetylene can be converted to other high value commodity chemicals by applying established chemical processes down stream of the reactor.
- Table 3 is a condensation of information relating to application of this system to already proven end products. It lists reactants and plasma gas combinations that have successfully produced the identified products.
- the plasma gas was changed to a mixture of Ar, He, and H 2 in the volume ratio of 65:32.5:2.5 respectively. This also increased the arc voltage and minimized the radiative heat loss from the plasma to the cooled anode thus maximizing both the enthalpy (energy content) and temperature, while still providing sufficient hydrogen for reaction with the fluorine (F 2 +H 2 ⁇ 2HF) and the formation of uranium-metal in the condensation region of the nozzle and reactor.
- the final problem to be solved was optimization of the injector to insure “good” mixing of the UF 6 with the plasma gas.
- a UF 6 feed system which would provide UF 6 at controlled temperature (between about 10° and about 100° C.) and elevated pressure (between 40 and about 75 psi) was designed.
- the UF 6 gas was mixed with an argon carrier gas and transversely injected at velocities ranging from 100-600 m/s. Operation of the injector at these velocities and avoidance of injector plugging and erosion required a reduction of the injector orifice size to 1-2.5.
- the optimum injection was found to be around 200 m/s. This condition resulted in adequate mixing and a successful experiment.
- ultrafine titanium dioxide ceramic powder obtained by oxidizing titanium tetrachloride in an oxygen enriched plasma gas. This system has been successfully used to produce an ultrafine particle size range of less than 500 nanometers, with 10-100 nanometers being the preferred range. The particles have been successfully produced within a narrow size range, meaning that 90 percent of the particles would fall within a 25 nanometer size range.
- the reaction chamber, converging/diverging nozzle and downstream cooling section were constructed of copper coated with an alumina type ceramic.
- the purpose of the ceramic was to prevent corrosion of the cooper by HCl produced in this process and reduce heat loss from the reaction zone.
- the reactor chamber for this original system test was 2.0 cm in diameter by 10.0 cm in length.
- the quench section consisted of a 90° included angle converging section followed by a 3.0 mm diameter throat and a 90° included angle diverging section issuing into a 4.0 cm diameter by 20 cm long cool down section.
- Four tangential hydrogen gas jets (1.0 mm diam) were placed in the diverging section of the nozzle approximately 5 mm downstream from the nozzle throat. Injection of cold hydrogen gas at this point seemed to improved yields of titanium. It was later learned that even better quenching could be accomplished by reducing the expansion angle of the diverging section of the nozzle to less than a 20° included angle, with the optimum diverging included angle being 6° to 14°.
- Titanium metal powder production in the early laboratory device was on the order of 0.1 to 0.5 grams per hour. This yield was improved to 0.5 to 1.0 gram per hour by (1) optimizing the geometry of the reactor: (2) addition of 1 to 5% hydrogen to the argon plasma gas to increase heat to the process while also preheating the hydrogen reductant for reaction with titanium tetrachloride; (3) injecting liquid or vaporized titanium tetrachloride into the reaction zone with a minimum of carrier gas; and (4) use of hydrogen as the carrier gas.
- reaction zone geometry was optimized by conducting two dimensional modeling of the fluid dynamics of such a system. Modeling results determined that reaction zone diameter should be no larger than 200% of the plasma torch anode exit diameter with the optimum being 110% to 150%. This prevents recirculation of reaction gases in the reaction zone which would contribute to undesirable side reactions and decrease product yields.
- Gas temperatures were measured experimentally along an elongated reaction section and were also modeled using a two dimensional fluid dynamics model to determine the optimum length of the reaction zone before the converging section.
- a reaction zone length was chosen from this data for a given plasma input power level, plasma gas flow, and reactant input rate which would result in gas temperatures at the entrance to the nozzle throat to be greater than the required equilibrium temperature of the desired end product—4000 K (for production of titanium).
- a high aspect ratio converging section was designed such that the radius of the convex and concave surfaces leading into the nozzle throat were approximately equal to the diameter of the nozzle throat. This converging geometry allows achieving the highest possible velocity at the entrance to the nozzle throat while limiting heat loss to the walls of the converging section or separation of the gas flow from the converging surface.
- the optimum area (diameter) of the nozzle throat was calculated from equations available in texts pertaining to nozzle design.
- the nozzle throat was designed so that with the temperature, gas composition, mass flow, and pressure of the gas entering the nozzle known (or estimated) sonic or near sonic gas velocities are achieved in the nozzle throat.
- To achieve maximum cooling (temperature drop) the nozzle throat should be as short as possible.
- T 0 and a 0 are the gas temperature and speed of sound respectively in the reaction zone.
- T 0 and a 0 are the gas temperature and speed of sound respectively in the reaction zone.
- the divergence angle and area at the exit of the diverging nozzle were determined from standard texts on fluid dynamics and aerospace rocket motor design. In addition, two dimensional models of fluid flow under expected experimental conditions were also used to optimize the divergence angle and exit area of the nozzle. It was concluded that the optimum divergence included angle was less than 35° and preferably in the range of 10° to 14° for optimum expansion and acceleration of the gas. The maximum exit area (diameter) of the diverging nozzle was again determined by calculation from equations available in standard texts on fluid flow and rocket engine design.
- the maximum allowable nozzle exit area depends on the mass flow through the nozzle and pressure difference between the reaction zone and the downstream cooling section. Choice of too large an expansion angle or too large an exit area will result in the gas flow “peeling off” or separating from the wall, which results in the undesirable conditions of turbulence, gas recirculation, gas reheating. and side or back reaction degradation of the desired end products.
- the purpose of the cool down section of the plasma fast quench reactor device is to reduce the gas velocity while removing heat energy (which results from the decrease in velocity) in the gas at a rate sufficient to prevent the gas from increasing in kinetic temperature. Passage of the gaseous stream through the restrictive nozzle opening reduces its kinetic temperature, but remove no energy from the gas. The exiting gaseous stream is slowly warmed as some random motion of the gaseous contents is restored. This heat must be immediately removed from the system as it is produce produced, thereby maintaining the kinetic temperature of the resulting gaseous stream at a desired equilibrium level and preventing back reactions downstream from the nozzle.
- Plasma quench processes for production of ultrafine materials require product collection capability downstream of the quench nozzle, preferably downstream of the cool down section.
- Bench scale experiments to date have used cyclonic collectors of standard dimensions described in the literature for gas and mass flows several time smaller than called for in the literature. This accommodates sonic or near sonic gas velocities through the cyclones, which allows efficient removal of ultrafine material (10 to 50 nm diameter powders).
- the third process parameter that determines the temperature drop across the nozzle is the ratio of the up stream pressure (P 0 , in reaction zone) to the downstream pressure (P 1 , cool down zone).
- P 0 /P 1 P 1 /P 0 0.01 to 0.26 was maintained.
- the experimental systems were operated with the reaction zone pressure of approximately 700 to 800 Tar (ca. 1 atm.) and downstream pressure maintained between 10 and 200 Tar (0.26 to 0.01 atm.).
- the low downstream pressure was accomplished using a mechanical vacuum pump.
- the quench system would be designed to operate with elevated pressures in the plasma torch and reaction chamber of 5 to 10 atmospheres pressure. This would accomplish the desired pressure drop across the nozzle while reducing a possibly eliminating the need for a vacuum device to lower the pressure on the downstream side of the nozzle.
- a bench sale reactor was constructed for synthesis of titanium, vanadium, aluminum, and TiN Alloys. This equipment was designed for operation at 12 KW input power to the plasma torch, using a plasma gas flow of 50 scfh and a plasma gas made up of 95% argon and 5% hydrogen gas. The equipment used to produce these materials consisted of a small bench scale plasma torch operated at 12 kW electrical input power attached to a reactor section, quench nozzle, cyclone powder collector, liquid nitrogen cold trap to collect by-product HCL and mechanical vacuum pump.
- titanium tetrachloride was heated above its boiling point and injected into the reaction chamber at the junction between the plasma torch and the reaction section.
- the reaction section, quench nozzle, and expansion chamber were constructed of water cooled nickel.
- the reaction section was 11.0 mm inside diameter and 150.0 mm in length.
- the quench nozzle section consisted of a high aspect ratio converging section followed by a 6.2 mm nozzle, and 12° included angle expansion section followed a 20.0 mm I.D., 50.0 cm cool down section.
- the cooled mixture of titanium powder and gas was passed through two sonic cyclone particle separators to collect the ultrafine powder. Hydrogen chloride vapor was condensed out in a liquid nitrogen cooled cold trap to prevent damage to the mechanical vacuum pump down stream from the particle collection. Titanium was produced according to equation (1) below:
- Ultrafine vanadium metal powder was produced using the bench scale apparatus described above. Vanadium tetrachloride liquid (B.P 145° C.) was heated to vapor and injected in the same manner as titanium tetrachloride described above with hydrogen carrier gas. Ultrafine vanadium metal powder was produced at the rate of a 0.5 gram per hour according to one of the following equations:
- An ultrafine powder consisting of an alloy of titanium and vanadium was produced by two methods.
- Method 1 used a mixture of solid vanadium trichloride dissolved in liquid titanium tetrachloride. This mixture was then heated to vapor and injected into the plasma quench reactor in the same manner as with titanium above.
- Method 2 vaporized liquid vanadium tetrachloride and vaporized liquid titanium tetrachloride were injected into the plasma quench reactor using separate injectors locate 1 in the same axial position but 180° apart on the circumference of the reactor.
- the chemical equations used are:
- Ultrafine aluminum metal powder was produced by vaporizing (subliming) solid aluminum trichloride in a specially designed oven and carried into the plasma quench reactor in a stream of hydrogen gas in the manner described for titanium above. Special care was needed to insure all sections of the injection system were maintained above 200° C., to prevent formation of solid aluminum trichloride.
- the process utilized the following equation:
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Abstract
Description
TABLE 2 | ||||
Reaction | Temperature K. | Log KP (or In SS) | ||
C(g) = C(s) | 3200 | −0.18 | ||
3000 | 0.17 | |||
2800 | 0.59 | |||
½C2(g) = C(s) | 3400 | −1.77 | ||
3200 | −1.61 | |||
3000 | 0.41 | |||
½C3(g) = C(s) | 3200 | −1.58 | ||
3000 | 1.39 | |||
2800 | 2.55 | |||
½C2H(g) = C(s) + |
3000 | 0.86 | ||
2500 | 1.17 | |||
2000 | 2.8 | |||
½C2H2(g) = C(s) + 1/ |
2000 | −5.48 | ||
1500 | −8.28 | |||
TABLE 3 | |||||
Injection | Injection | C-D Nozzle | |||
Reactants | Plasma Gas | Method | Position | Shape (angle) | Products |
TiCl4 + H2 | Argon/ | TiCl4 + H2 @ | 3.0-6.0 mm | C-45° to bell | Titanium |
Hydrogen | 180-200° C. | from Torch | shaped | Metal + | |
exit | D-26-6° | HCL gas | |||
VCl4 + H2 | Argon/ | VCl4 + H2 @ | 3.0-6.0 mm | C-45° to bell | Vanadium |
Hydrogen | 180-200° C. | from Torch | shaped | Metal + | |
exit | D-25-6° | HCl gas | |||
AlCl3 + H2 | Argon/ | AlCl3 + H2 @ | 3.0-6.0 mm | C-45° to bell | Aluminum |
Hydrogen | 120-150° C. | from Torch | shaped | Metal + | |
exit | D-25-6° | HCL gas | |||
TiCl4 + | Agron/ | TiCl4/VCL3 or 4 + | 3.0-6.0 mm | C-45° to bell | TiV Alloy |
VCl3 (or | Hydrogen | H2 @ | from Torch | shaped | powder + |
VCl4) + H2 | 180-200° C. | exit | D-25-6° | HCl gas | |
TiCl4 + | Argon/ | TiCl4 (liq) @ | 3.0-6.0 mm | C-45° to bell | TiB2 |
BCl3 + | Hydrogen | 50 psi + | from Torch | shaped | composite |
H2 | BCl3 (gas) @ | exit | D-25-6° | Ultrafine | |
50 psi + | powder | ||||
H2 | ceramic | ||||
TiCl4 + O2 | Argon/ | TiCl4 (liq) @ | TiCl4 (liq) | C-Bell Shaped | Ultrafine |
Oxygen or | 50 psi | 1-3 mm from | D-10 to 25° | TiO2 ceramic | |
Oxygen | O2 (gas) @ | torch | included | powder | |
50 psi | exit | ||||
WF6 + H2 | Agron/ | WF6 (g) @ | WF6 (g) at | C-Conical | Ultrafine |
Hydrogen/or | 50 psi, | torch exit | D-Conical 10- | Tungsten | |
Hydrogen | 80-120° C. | 20° included | Metal | ||
powder | |||||
UF6 + 2 | Argon | UF6 (g) @ | UF6 (g) at | C-Conical | Ultrafine |
Argon | Hydrogen/ | 40-75 psi, | torch exit | D-Conical | Uranium |
Helium | 20-100° C. | 20° included | metal | ||
powder | |||||
H2 + CH4 | Argon/ | CH4 (gas) @ | interior of | C-Bell Shaped | 80% + |
Hydrogen or | 50-100 psi | torch or 1-3 | D-10 to 25° | Acetylene | |
Hydrogen | mm from | included | Lesser | ||
amounts of | |||||
ethylene & | |||||
carbon(s) | |||||
Argon + | Argon | CH4 (gas) @ | Interior of | C-Bell shaped | Ultrafine |
CH4 | 56-100 psi | torch or | D-10 to | carbon black | |
1-3 mm from | 25° included | powder | |||
torch exit | |||||
Claims (73)
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US09/569,146 USRE37853E1 (en) | 1995-03-14 | 2000-05-11 | Fast quench reactor and method |
Applications Claiming Priority (2)
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US08/404,395 US5749937A (en) | 1995-03-14 | 1995-03-14 | Fast quench reactor and method |
US09/569,146 USRE37853E1 (en) | 1995-03-14 | 2000-05-11 | Fast quench reactor and method |
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US08/404,395 Reissue US5749937A (en) | 1995-03-14 | 1995-03-14 | Fast quench reactor and method |
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US08/404,395 Ceased US5749937A (en) | 1995-03-14 | 1995-03-14 | Fast quench reactor and method |
US09/076,922 Expired - Lifetime US5935293A (en) | 1995-03-14 | 1998-05-12 | Fast quench reactor method |
US09/569,146 Expired - Lifetime USRE37853E1 (en) | 1995-03-14 | 2000-05-11 | Fast quench reactor and method |
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US08/404,395 Ceased US5749937A (en) | 1995-03-14 | 1995-03-14 | Fast quench reactor and method |
US09/076,922 Expired - Lifetime US5935293A (en) | 1995-03-14 | 1998-05-12 | Fast quench reactor method |
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US (3) | US5749937A (en) |
EP (1) | EP0815271A4 (en) |
JP (1) | JP4139435B2 (en) |
CN (1) | CN1052759C (en) |
AU (1) | AU694024B2 (en) |
BR (1) | BR9607210A (en) |
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JPH11502760A (en) | 1999-03-09 |
AU694024B2 (en) | 1998-07-09 |
US5935293A (en) | 1999-08-10 |
AU5423596A (en) | 1996-10-02 |
BR9607210A (en) | 1997-11-11 |
CN1182456A (en) | 1998-05-20 |
EP0815271A4 (en) | 1998-06-10 |
CA2215324C (en) | 2005-10-25 |
CN1052759C (en) | 2000-05-24 |
NO974225L (en) | 1997-11-04 |
WO1996028577A1 (en) | 1996-09-19 |
NO318231B1 (en) | 2005-02-21 |
US5749937A (en) | 1998-05-12 |
EP0815271A1 (en) | 1998-01-07 |
NO974225D0 (en) | 1997-09-12 |
CA2215324A1 (en) | 1996-09-19 |
JP4139435B2 (en) | 2008-08-27 |
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