A fluidized-bed reactor for producing hydrogen from methane by steam reforming includes a flow splitter that splits a dense-phase flow of a gas having entrained calcium oxide particles into a plurality of equal flow streams. The reactor also incorporates an orifice plate having at least one high-vel
A fluidized-bed reactor for producing hydrogen from methane by steam reforming includes a flow splitter that splits a dense-phase flow of a gas having entrained calcium oxide particles into a plurality of equal flow streams. The reactor also incorporates an orifice plate having at least one high-velocity, rocket-style impinging injector for injecting reactants into the reactor bed. The injector includes a central orifice extending perpendicularly through the plate, and one or more adjacent peripheral orifices that extend through the plate at such an angle that respective streams of reactants injected into the reactor bed through the peripheral orifices impinge on a stream of reactants injected vertically into the reactor bed through the central orifice. The injector cooperates with adjacent base-bleed orifices in the plate to provide a uniform distribution and rapid mixing of the calcium oxide particles with a steam/methane gas mixture across the entire bottom of the reactor bed.
대표청구항▼
What is claimed is: 1. A high-velocity, rocket-style impinging injector for injecting reactants into the bed of a two-particle, fluidized-bed reactor of a type used for the production of hydrogen from methane by a steam reforming process, said injector comprising: a plate disposed horizontally with
What is claimed is: 1. A high-velocity, rocket-style impinging injector for injecting reactants into the bed of a two-particle, fluidized-bed reactor of a type used for the production of hydrogen from methane by a steam reforming process, said injector comprising: a plate disposed horizontally within the reactor and below the fluidized bed thereof, the plate having: a central orifice extending substantially perpendicularly through the plate; a peripheral orifice disposed adjacent to the central orifice and extending through the plate at a transverse angle relative to the central orifice such that a stream of reactants injected into the reactor bed through the peripheral orifice impinges on a stream of reactants injected into the reactor bed through the central orifice; and a plurality of base-bleed orifices disposed around the injector and extending substantially perpendicularly therethrough, wherein the peripheral orifice is located closer to the central orifice than each of the base-bleed orifices. 2. The injector of claim 1, further comprising a plurality of the peripheral orifices arranged in the plate such that the streams of reactants respectively injected therethrough impinge on the stream of reactants injected through the central orifice at a common, acute angle. 3. The injector of claim 2, wherein the respective streams of reactants injected through the peripheral orifices impinge on the stream of reactants injected through the central orifice at a common point. 4. The injector of claim 3, wherein: the stream of reactants injected through the central orifice comprises a gas having particles of a solid entrained therein at about the static-bed bulk density of the particles; and, the stream of reactants injected through the peripheral and the base-bleed orifices comprises a mixture of gases. 5. The injector of claim 4, wherein: the stream of gas and entrained particles has an axial velocity of between about 10 to about 30 ft./sec.; the solid comprises calcium oxide particles have a static-bed bulk density of about 30 lbm/ft3; and, the mixture of gases comprises steam and methane. 6. The injector of claim 5, wherein: the injector comprises four peripheral orifices; the pressure in the fluidized bed of the reactor is about 7.8 atm absolute; the ratio of the mass of the calcium oxide injected through the central orifice to the mass of the steam and methane mixture injected through the peripheral orifices is about 10 to 1; the steam and methane mixture is injected into the reactor bed through the peripheral orifices at a velocity of about 650 ft./sec; the percentage of the total flow of the steam and methane mixture injected into the reactor bed through the peripheral orifices is about 10 per cent; the percentage of the total flow of the steam and methane mixture injected into the reactor bed through the base-bleed orifices is about 90 per cent; and, the total differential pressure drop across the plate is about 13 psi. 7. A one-step fluidized-bed reactor for the production of hydrogen from methane by a steam reforming process, said reactor comprising: an elongated vertical chamber; a plate disposed horizontally within a lower portion of the reactor, the plate defining an upper, fluidized-bed chamber, a lower, gas-manifold chamber, at least one high-velocity, rocket-style impinging injector including a central orifice extending through the plate and at least one peripheral orifice disposed adjacent to the central orifice and extending through the plate at a transverse angle relative to the central orifice, and a plurality of base-bleed orifices disposed around the impinging injector and extending substantially perpendicularly through the plate that fluidly connect the upper fluidized-bed chamber and the lower gas-manifold chamber; and a bed of particles disposed in the upper, fluidized bed chamber, the bed of particles including nickel-plated alumina particles. 8. The reactor of claim 7, wherein the transverse angle is an acute angle. 9. The reactor of claim 7, further comprising: a dense-phase flow splitter having an outlet tube that includes an outlet end that is coupled to the central orifice of the injector. 10. The reactor of claim 9, wherein: the stream of gas and entrained particles has an axial velocity of between about 10 to about 30 ft./sec.; and, the calcium oxide particles have a static-bed bulk density of about 30 lbm/ft3. 11. The reactor of claim 10, wherein: the injector comprises four peripheral orifices; the pressure in the fluidized bed of the reactor is about 7.8 atm., absolute; the ratio of the mass of the calcium oxide injected through the central orifice to the mass of the steam and methane mixture injected through the peripheral orifices is about 10 to 1; the steam and methane mixture is injected into the reactor bed through the peripheral orifices at a velocity of about 650 ft./sec; the percentage of the total flow of the steam and methane mixture injected into the reactor bed through the peripheral orifices is about 10 per cent; the percentage of the total flow of the steam and methane mixture injected into the reactor bed through the base-bleed orifices is about 90 per cent; and, the total differential pressure drop across the plate is about 13 psi. 12. The reactor of claim 7, wherein the stream of second reactants comprises entrained solid particles and the stream of first reactants is substantially free of solid particles. 13. The reactor of claim 12, further comprising first particles disposed in the upper fluidized-bed chamber and second, different particles as the entrained solid particles. 14. The reactor of claim 13, wherein the first particles comprise nickel-plated alumina, and the second particles comprise calcium oxide. 15. The reactor of claim 7, wherein the central orifice and the at least one peripheral orifice extend along respective axes that define the transverse angle. 16. The reactor of claim 7, wherein the peripheral orifice is located closer to the central orifice than each of the plurality of bleed orifices.
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