This disclosure relates to reactor systems and methods of decomposing ammonia.
A fluid can be decomposed, that is, broken up into its constituent components, by various methods and industrial processes. Some fluids can be decomposed by mechanical processes. Other fluids can be decomposed by chemical processes. Some fluids can be decomposed in conjunction with other industrial processes, such as power generation.
The present disclosure relates to reactor systems and methods of decomposing ammonia.
Implementations of the present disclosure include a catalyst reactor including an elongated conduit extending along a longitudinal axis. The elongated conduit can include a wall defining an interior cavity, an inlet configured for receiving a first fluid, and an outlet to flow the first fluid out of the elongated conduit, the wall having an interior cross-section defined by a major axis, W, and a minor axis, H, the major axis and the minor axis defining an aspect ratio,
wherein the aspect ratio is greater than 2.0; and a catalytic structure disposed within the interior cavity of the elongated conduit.
In some embodiments, the catalytic structure has a cross-section shape is the same shape as the interior cross-section of the elongated conduit.
In some embodiments, the catalytic structure comprises a plurality of catalytic structures. In some embodiments, the catalytic structure is a catalytic monolith. In some embodiments, the catalytic structure is fixedly coupled to the elongated conduit. In some embodiments, the catalytic structure is coupled to the elongated conduit by an interference fit. In some embodiments, the catalytic structure comprises a ceramic, a metal, or combinations thereof. In some embodiments, the catalytic structure comprises a metal foam substrate. In some embodiments, the catalytic structure comprises a plurality of catalyst pellets.
In some embodiments, the elongated conduit comprises a u-shaped section. In some embodiments, the catalyst structure is disposed within the elongated conduit and configured to change a composition of the first fluid responsive to a transfer of heat across the wall of the elongated conduit. In some embodiments, the elongated conduit includes a first shell; and a second shell configured to couple to the first shell; wherein the first and second shells couple together to define the elongated conduit.
In some embodiments, the elongated conduit further comprises a stamped portion that recesses the wall in a transverse direction toward a central axis of the conduit wall. In some embodiments, the stamped portion comprises two opposing wall portions that are each recessed in a transverse direction toward a central axis of the conduit and coupled together. In some embodiments, the elongated conduit comprises a plurality of stamped portions. In some embodiments, the stamped portion is at least one of a circular shape, a square shape, or a rectangular shape.
In some aspects, a catalyst reactor system includes a reactor housing defining an enclosure, the housing including a main inlet configured for receiving a heat exchanging fluid and a main outlet for flowing the heat exchanging fluid out of the housing; a catalyst reactor assembly disposed within the enclosure of the reactor housing such that the heat exchanging fluid flows along an exterior of the catalyst reactor assembly. The catalyst reactor assembly includes first and second catalyst reactors. Each catalyst reactor includes an elongated conduit comprising a wall defining an interior cavity and an exterior surface configured for transferring heat from the heat exchanging fluid to the interior cavity, an inlet configured for receiving a first fluid, an outlet configured to flow the first fluid out of the elongated conduit, the elongated conduit having an interior cross-section defined by a major dimension and a minor dimension, the major and minor dimensions defining an aspect ratio,
which has a value greater than 2.0; and a catalytic structure disposed within the interior cavity of the elongated conduit; an inlet conduit fluidically coupled to the inlets of the first and second catalyst reactors; and an outlet conduit fluidically coupled to the outlets of the first and second catalyst reactors.
In some embodiments, the inlet conduit further comprises an inlet flow control device configured to control the flow of the first fluid to the first and second catalyst reactors. In some embodiments, the outlet conduit further comprises an outlet flow control device configured to control the flow of the first fluid from the first and second catalyst reactors. In some embodiments, the first and second catalyst reactors are thermo-chemical recuperators.
In some embodiments, the elongated conduit is angled relative to the heat exchanging fluid to induce a turbulence in the heat exchanging fluid.
In some embodiments, the catalyst reactor system is incorporated in a plant comprising at least one of a power generation plant, a chemical reactor, a nuclear reactor, a biological reactor, and a chemical extraction process. In some embodiments, the catalyst reactor system includes a duct burner disposed in the reactor housing, the duct burner configured to mix a portion of the first fluid with the heat exchanging fluid, and burn the mixture of the portion of the first fluid and the heat exchanging fluid to raise the temperature of the heat exchanging fluid.
In some embodiments, the catalyst reactor assembly is positioned proximal to an output of a reduction catalyst reactor of the power generation plant such that a threshold quantity of heat is transferred from the reduction catalyst reactor to the catalyst reactor assembly. In some embodiments, the catalyst reactor assembly is positioned proximal to an output of an oxidation catalyst reactor of the power generation plant such that a threshold quantity of heat is transferred from the oxidation catalyst reactor to the catalyst reactor assembly.
In some embodiments, the elongated conduit comprises a u-shaped section. In some embodiments, the catalyst structure is disposed within the elongated conduit and configured to change a composition of the first fluid responsive to a transfer of heat from the heat exchanging fluid across the wall of the elongated conduit.
In some embodiments, the catalyst reactor system includes a pre-heating system, a vaporizing system, a combustor, or combinations thereof. In some embodiments, the catalyst reactor system includes a duct burner.
In certain aspects, a method for thermal decomposition includes receiving a first fluid at a first temperature from an inlet conduit at a catalytic reactor assembly. The catalyst reactor assembly can include first and second catalyst reactors. Each catalyst reactor can include an elongated conduit comprising a wall defining an interior cavity and an exterior surface configured for transferring heat from the heat exchanging fluid to the interior cavity, an inlet configured for receiving a first fluid, an outlet configured to flow the first fluid out of the elongated conduit, the elongated conduit having an interior cross-section defined by a major dimension and a minor dimension, the major and minor dimensions defining an aspect ratio,
which has a value greater man 2.0, and a catalytic structure disposed within the interior cavity of the elongated conduit. The catalyst reactor assembly can be positioned within a reactor housing defining an enclosure. The housing can include a main inlet configured for receiving a heat exchanging fluid and a main outlet for flowing the heat exchanging fluid out of the housing. The method can include receiving the heat exchanging fluid at a second temperature at the main inlet of the reactor housing; flowing the heat exchanging fluid at the second temperature from the main inlet of the reactor housing to the first and second catalyst reactors; receiving the heat exchanging fluid at the second temperature at the first and second catalyst reactors; flowing the heat exchanging fluid to at least a portion of the exterior surfaces of the first and second catalyst reactors such that the heat exchanging fluid transfers heat to the first fluid across the walls of the conduits; and heating the first fluid to a third temperature such that the first fluid changes its composition.
In some embodiments, the method can include flowing the heat exchanging fluid to the main outlet; and exhausting the heat exchanging fluid to an atmosphere. In some embodiments, the first fluid comprises an ammonia, heating the first fluid to a third temperature such that the first fluid changes its composition comprises decomposing the ammonia responsive to the transfer of heat from the heat exchanging fluid to the first fluid.
In some embodiments, the method includes flowing the heat exchanging fluid to at least a portion of the exterior surfaces of the first and second catalyst reactors such that the heat exchanging fluid transfers heat to the first fluid across the walls of the conduits comprising inducing turbulence in the heat exchanging fluid as the heat exchanging fluid flows to at least the portion of the exterior surfaces of the first and second catalyst reactors to increases the transfer of heat from the heat exchanging fluid to the first fluid.
Particular implementations of the subject matter described in this specification can be implemented so as to realize one or more of the following advantages.
Implementations of the present disclosure can advantageously reduce exhaust pollution to the environment. For example, with the systems and methods provided herein, ammonia can be used to decompose into hydrogen and nitrogen at concentrations suitable for complete combustion and, thereby, reduce the amount of released nitrogen oxides that pollutes the environment. In some cases, the systems and methods described herein can use ammonia for power generation to reduce carbon emissions to the environment. As will be discussed in the later sections, various implementations of the present disclosure can increase power generation efficiency. In some embodiments, preexisting inefficient systems (e.g., heat recovery steam generators in power generation systems) can be replaced with more efficient systems and assemblies described herein. For example, in some embodiments, the systems provided herein include a selective catalytic reduction catalyst that advantageously reduces nitrogen oxides to increase the exhaust temperature, generate higher temperatures for waste heat for recovery operations, and, ultimately, reduce the waste heat lost to the environment. In some embodiments, the systems and methods provided herein can increase the heat transfer between system components, and, in turn, increase the power generation efficiency.
Various embodiments of the present disclosure provides systems and methods can provide efficient ammonia combustion, reduce NOx passively with unburned NH3, and/or increase thermal efficiency with a thermochemical recuperation reactor (TCR). In some embodiments, the systems and reactors disclosed herein can provide a simple, efficient design that is easy to manufacture and install in both new and existing structures.
The details of one or more embodiments of the invention are set forth in the accompanying drawings and the description below. Other features, objects, and advantages of the invention will be apparent from the description and drawings, and from the claims. The features described below in separate embodiments can be combined in alternate embodiments.
Like reference numbers and designations in the various drawings indicate like elements.
The present disclosure relates to reactor systems and methods of thermally decomposing ammonia. The reactor systems provided herein can include one or more catalyst reactors configured to thermally decompose ammonia for combustion-fueled generating systems. In some embodiments, the reactor systems provided herein can be incorporated into other heat-producing systems, including, but not limited to, a system that includes a chemical reactor, a nuclear reactor, a biological reactor, a reactor configured for a chemical extraction, or combinations thereof.
The systems and catalytic reactors described herein can include a conduit having a structure extending along a longitudinal axis. The catalytic reactor can include one or more catalyst structures within the conduit structure.
The conduit can be elongate. The conduit can have a wall defining an interior cavity, an inlet to receive a fluid (e.g., ammonia), and an outlet to flow a fluid (e.g., decomposed ammonia) out of the conduit. The wall can have an interior cross-section defined by a major axis, W, and a minor axis, H. The major axis and the minor axis defining an aspect ratio (see Equation 1 provided below), wherein the aspect ratio α is greater than 2.0. One or more catalytic structures can be positioned within the interior cavity of the elongated conduit.
Systems provided herein can include multiple catalyst reactors that are fluidically coupled together in an assembly. In some embodiments, the catalyst reactor provided herein can include a reactor housing defining an enclosure. The housing can include an inlet for receiving an inlet fluid (e.g., heat exchanging fluid) and an outlet for flowing an outlet fluid (e.g., the heat exchanging fluid) out of the housing. The catalyst reactor assembly can be arranged within the enclosure of the reactor housing such that the heat exchanging fluid flows along at least a portion of the exterior of one or more of the catalyst reactors. The catalyst reactor assembly provided herein can include an inlet conduit fluidically coupled to the inlets of the catalyst reactors and an outlet conduit fluidically coupled to the outlets of catalyst reactors.
The power generation system 102 includes a generator 104 configured for generating electricity for the system. The generator 104 is powered by a gas turbine 106. The gas turbine 106 can be fueled or powered by the combustion of ammonia. Alternatively or in additionally, in some embodiments, the gas turbine 106 can be fueled by natural gas, a mixture of ammonia and natural gas, or any other petroleum based fuel.
Air can enter the gas turbine 106 at inlet 108 and be compressed by a compressor 110. The compressed air flows from the compressor 110 to a combustor 112. Fuel (in the form of ammonia, natural gas, or an ammonia/natural gas mixture) is flowed into the combustor 112. The compressed air and the fuel combine, mix, and are ignited in the combustor 112 to expand and flow to a turbine 114. Igniting the air/fuel mixture raises the temperature of the air/fuel mixture to form a hot air/fuel mixture. The hot air/fuel mixture expands in the turbine 114 causing the turbine 114 to rotate (now a hot expanded air/fuel mixture). The hot expanded air/fuel mixture can be referred to as a heat exchanging fluid.
The turbine 114 can be coupled to and rotate (e.g., powers) a shaft 116. The compressor 110 and the generator 104 can be both coupled to and rotated by the shaft 116. The shaft 116 can rotate the compressor 110 to compress the air as previously described. The shaft 116 can rotate the generator 104 to generate electricity as previously described.
The hot expanded air/fuel mixture can flow from the turbine 114 to an enclosure 118 (or a sealed housing). In some embodiments, the enclosure 118 can be an exhaust system for the power generation system 102. The enclosure 118 can include at least one inlet 120. The inlet 120 can receive the hot expanded air/fuel mixture from the turbine 114. The enclosure 118 can include at least one outlet 122. The hot expanded air/fuel mixture can flow from the inlet 120 through the enclosure 118 to the outlet 122. The hot expanded air/fuel mixture can exit the enclosure through the outlet 122 to an atmosphere 124 (the environment). In some embodiments, the flow of the hot expanded air/fuel mixture can optionally be controlled by an upstream valve (not shown), for example, in the combustor.
As the hot expanded air/fuel mixture flows through the enclosure 118, the mixture can flow across the catalyst reactor system 100. The catalyst reactor system 100 is described in detail below in reference to the example provided by
The catalyst reactor system can be housed in the enclosure 118 such that the hot expanded air/fuel mixture flows across the catalyst reactor system 100, transferring heat into the catalyst reactor system 100.
The catalyst reactor system 100 can receive ammonia from at least one inlet 126. The ammonia can flow through the catalyst reactor system 100 such that the decomposition products of the ammonia and any remaining undecomposed ammonia flow to at least one outlet 128. As the ammonia flows through the catalyst reactor system 100, the ammonia can flow across one or more catalytic structures (described later in reference to
The power generation system 102 can optionally include a heat exchanger 130. The heat exchanger 130 can receive a supply of ammonia (e.g., anhydrous ammonia). The heat exchanger 130 can be fluidically coupled to the inlet 126 of the catalyst reactor system 100 to flow the ammonia to the catalyst reactor system 100. The heat exchanger 130 can be positioned within the enclosure 118. The heat exchanger 130 can receive the hot expanded air/fuel mixture to pre-heat the ammonia before the ammonia flows into the catalyst reactor system 100.
The power generation system 102 can optionally include a duct burner 132. The duct burner 132 can receive a flow of ammonia. In some embodiments, the flow of ammonia to the duct burner 132 can be controlled by a valve 134. The duct burner 132 can include a conduit 136 to receive and flow the ammonia. The duct burner 132 can include one or more nozzles 138 extending radially from the conduit 136 to receive and inject the ammonia from the conduit 136 into the enclosure 118. As the ammonia is injected into the enclosure 118 from the nozzles 138, the ammonia can be ignited. In some embodiments, burning the ammonia can raise the temperature of the air/fuel mixture flowing through the enclosure 118.
The catalyst reactor system 100 can optionally include at least one valve 140 configured to control the flow of ammonia to the heat exchanger 130. In some embodiments, a valve can be used to control the flow of ammonia to the catalyst reactor system 100.
Referring to
Still referring to
In some embodiments, the outlet conduit 206 can be common to some or all the catalyst reactor assemblies 200a, 200b, and 200c. The ammonia can flow into the inlet 126. The ammonia can flow through each of the catalyst reactor assemblies 200a, 200b, and 200c. Nitrogen, hydrogen, and undecomposed ammonia can flow from the catalyst reactor assemblies 200a, 200b, and 200c into the outlet conduit 206. The nitrogen, hydrogen, and undecomposed ammonia can flow through the outlet conduit 206 to the outlet 128. An outlet terminal end 208 of the outlet conduit 206 can be capped to terminate the flow of nitrogen, hydrogen, and undecomposed ammonia and direct the nitrogen, hydrogen, and undecomposed ammonia from each of the catalyst reactor assemblies 200a, 200b, and 200c and force the nitrogen, hydrogen, and undecomposed ammonia to the outlet 128.
Referring to
The catalyst reactor assembly can include the elongated conduit 302. The elongated conduit 302 can extend along a longitudinal axis 304. The elongated conduit 302 is defined by a wall 306. The wall 306 has an inner surface 308. The wall 306 and the inner surface 308 define an interior cavity 310. The elongated conduit 302 flows the ammonia from the inlet 312 to an outlet 316.
The wall 306 has an interior cross-section defined by a major axis, W, and a minor axis, H. The major axis, W, and a minor axis, H, define an aspect ratio,
The aspect ratio, α, was determined using the following method. Two equal-volume catalyst structures (described later), identically coated and under identical flow and thermal conditions were used. Resistance to heat transfer due to conduction and convection was be approximated by a single thermal resistance value, which is constant between the two geometries. The thermal resistance to heat transfer scales with the thermal path length moving from a hot exterior (exhaust-side) to an endothermic reaction interior (ammonia decomposing). Temperature is constant for a given exhaust temperature surrounding the catalyst assembly. Heat transfer rate scales with the available surface area exposed to the exhaust. Increasing heat transfer to the catalyst structure is accomplished by flattening the catalyst structure proportional to the product of surface area increase and the inversely proportional to the thermal resistance decrease (increase in conductance) over a baseline geometry cross-section (cylindrical tube). For the calculation of a surface area of a shape, see Equations 10-12, below.
Referring to
The benefit to the flatter catalyst structure is shown in
High rates of heat transfer from exhaust to reaction deplete energy from the exhaust flow, decreasing the temperature differential over that of the cylindrical profile. The assumption that heat transfer resistance is linear is discussed below. Given a constant linear resistance value R in W/m-k, resistance from R to a depth of 0.606 R is equal to that of the linear resistance halfway through the rectangular catalyst (H/2).
Heating to greater depths within the cylinder can become more difficult. Furthermore, the approximation that the resistance to heating scales with thermal path length in the cylindrical geometry cab slightly over-estimate the cylindrical heat rate, while also underestimating the benefit of the rectangular geometry.
V
cyl
=πr
2
L Equation 2
V
rect
LWH Equation 3
Assuming a constant space velocity, and therefore identical catalyst volumes, yields:
Vcyl=Vrect Equation 4
πr2L=LWH Equation 5
πr2=WH Equation 6
Defining a variable for the “flatness” of the rectangular catalyst, as discussed above, the aspect ratio is:
Defining W in terms of H yields the following equation:
W=αH Equation 7
Rewriting Equation 6 yields:
πr2=αH2 Equation 8
Simplifying to find H in terms of radius, a relationship between radius of a cylinder and the height of a rectangular prism is defined. For varied aspect ratios, the volume of the rectangular prism and the cylinder are equal, see for instance Table 2.
The height (H) and radius (R) are considered as the effective path-length across which heat must flow. The longer path length increases thermal resistance and decreases heating rate, assuming all other variables are held constant.
The other half of the heat rate estimation involves the relative surface area of the catalyst geometry. The generic surface areas of cylindrical and rectangular geometries are defined below.
SAsyl=2πrL Equation 10
SArect=2(W+H)L
The ratio of surfaces areas is, through several substitutions:
Assuming thermal properties and conditions on both cylindrical and rectangular catalysts are equal, an estimation of heat transfer rate increase can be obtained by the product of the ratio of surface areas the inverse of thermal path length (e.g., overall thermal conductivity).
The ratio of effective conductivities is given by the inverse ratio of thermal path lengths R over H/2. The H/2 term is included as heat enters the rectangular monolith from both ends.
The ratios are multiply together:
The critical aspect ratio, α, is the value at which the relative heat transfer of the two geometries is equal. Geometries having an aspect ratio value that is above the critical aspect ratio (e.g., rectangular geometries) transfer more heat.
The radial heat transfer in cylinders is not accounted for in this proof. Heat transfer is not linear as heat moves radially through a cylinder. Using the full volume of a cylinder may decrease the area upon which heat flows through.
In some embodiments, to acquire a higher surface-area to volume ratio, as is the case of a round tube, the tube may be flattened to produce an oval or slot profile. Aspect ratios at 2.0 or above provide heat-transfer advantages over a round (e.g., cylindrical) tube, as discussed above. In some embodiments, the aspect ratio is greater than or equal to 2.0 (e.g., greater than or equal to 2.5, greater than or equal 3.0, greater than or equal to 3.5, greater than or equal to 4.0, greater than or equal to 5.0, greater than or equal to 10, greater than or equal to 20, greater than or equal to 30, or greater than or equal to 50).
A thermal analysis can be used to establish an upper bound of the aspect ratio. Flattening the geometry, e.g., obtaining higher aspect ratios, decreases thermal resistance between the interior fluid and the exterior fluid. Low thermal resistance increases the average temperature of the catalyst and fluid inside, increasing activity and yield. Lowering thermal resistance can create diminishing yields, as eventually the interior catalyst and fluid are at a uniform temperature, limited by the convective heat transfer rate and the thermal resistance of the fixed heat exchanger wall thickness and internal convective rates. In this condition, the average temperature of the catalyst and internal fluid system are near the maximum temperature they can reach under their flow rates and initial temperatures. Treating the whole internal volume (Fluid+Catalyst) as a fixed mass, with temperature and an effective thermal conductivity, determining heat transfer using the Biot Number (Bi) facilitates quantification of performance.
Bi compares the rate of external convection to internal conduction and determines whether the internal conduction is sufficient to treat the inner volume as having uniform temperature. If conduction is sufficient such that the internal temperature variation is negligible, increasing the aspect ratio to decrease thermal resistivity does not result in further thermal benefit. This condition occurs when Bi≤0.1 and particularly when Bi«0.1.
The Biot Number (Bi) is defined as:
where h is the convective heat transfer coefficient defined as
k is the reactor conductivity defined as
and l is the reactor half-thickness, and t the reactor thickness.
To define a maximum width of a rectangular reactor unit, a constraint is common material sizes from which the reactor unit is stamped and welded. Widths of 48 inches are common for sheet stock, which is then cut to shorter lengths with a shear or other method. Wider widths may incur costs related to specially ordered stock and smaller width units can be easier to handle during manufacturing. This determines an upper bound on the aspect ratio once the thickness is determined.
Using the first Bi constraint above, in which Bi is less than or equal to 0.1, it is also true that
To determine a theoretical maximum aspect ratio, the minimum thickness is determined. Increasing convective rates and decreasing conduction rates results in a smaller thickness for thermal homogeneity. To consider from another angle, high conduction rates create conditions for a thick (e.g., high t) reactor cross-section and increased performance compared to low conduction rates. The term ‘thick’ in this case refers to the thermal path length, or the total length heat travels through the material before reaching a boundary. In the case of our flattened plate which is heated from both ends, this is half way through the physical thickness of the flattened plate. As thermal conductivity tends to be low in catalyst substrates due to large open areas, it is desirable to be thinner, e.g., high aspect ratios.
If convection is weak, a thinner plate does not increase and homogenize the internal temperatures. Internal temperatures are homogeneous when the internal temperatures are at a lower temperature than the external exhaust gases. High resistance at the convective boundary layer is where most of the temperature differential exists, leaving less to generate inhomogeneity in the reactor itself. High convective coefficients and high conductivity are desirable. To define a maximum aspect ratio, assumptions are made that conduction is low and convection is high. For example, an assumption is that the minimum conduction is equal to the effective conduction of the metal catalyst support and/or sheet which contain the catalyst, e.g., stainless steel properties.
Established ranges for forced convection of gas, as determined in a gas turbine are
Taking the largest convection rate to find our maximum aspect ratio:
This results in a thin plate. This provides an upper bound for the aspect ratio where thinner can become a manufacturing issue, though this is not theoretically limiting on manufacturing processes themselves. Above this aspect ratio provides diminishing additional thermal benefit under extreme conditions. For less extreme cases, (e.g., for example, 50≤α≤100, e.g., 75), it may be feasible to make a reactor section at 24″ and similar thicknesses to achieve a design resulting in an aspect ratio of ˜75 as well as facilitating easier manufacture. In some embodiments, the aspect ratio is less than or equal to 150 (e.g., less than or equal to 125, less than or equal 100, less than or equal to 80, less than or equal to 75, less than or equal to 70, less than or equal to 50, less than or equal to 20, or less than or equal to 10). In some embodiments, the aspect ratio is in a range from 2 to 150 (e.g., in a range from 5 to 125, in a range from 10 to 100, in a range from 50 to 80, in a range from 65 to 75, in a range from 70 to 80, in a range from 50 to 100, in a range from 20 to 125, in a range from 10 to 30, in a range from 20 to 50, in a range from 20 to 40, in a range from 5 to 20, or in a range from 10 to 20).
Additionally or alternatively, producing thicker and sturdier panels is possible for convections below
and/or about
An aspect ratio of 150 represents a theoretical upper bound based on assumptions for what is impractical for common real-world applications known in the art.
The internal heat generation (e.g., absorption) term due to chemical reaction is another factor for consideration which changes effective conduction within the reactor. In the non-limiting case described, the reactor absorbs heat from the chemical reactions, which increase the effective conductivity term by generating a greater temperature gradient than that without reaction. In the above analysis, a lower bound on this term is assumed so in the case of internal generation where conductivity goes up, the same heat exchange performance with smaller aspect ratio is achieved.
The aspect ratio upper limit of 150 is an upper bound as determined based on the assumptions described and is non-limiting for applications in which the assumptions are modified or alternative methods are utilized. Assuming a lower bound on the generation term embodies the condition where the internal fluid flows and absorbs heat without reacting. This is a condition in a preheating step as opposed to a reaction step. In conditions in which a reaction step is occurring, the methods and system described facilitate achieving comparable outcomes, e.g., part of a reactor section, or some of all reactor sections are used for pre-heating instead of reaction.
For the cylinder and rectangle described above, the effective resistance into the radial volume becomes equal to the half-height resistance of the rectangle at a radial depth of ˜0.41 of radius as described below. Cylindrical surface area is the same as rectangular surface area when considered for thermal resistance. An arbitrary and equal “conduction” value k is used to represent heat transfer. The effective length in rectangular resistance is equal to the H/2, which is also the outer radius of the cylinder/2. A critical depth for r2 yields an equivalent resistance to the rectangular resistance, and is non-negative.
Find the critical value for r2 is found by:
Under these conditions, as long as the thermal path length in the cylindrical baseline is greater than 0.394 r, the resistance is greater for the cylinder than the rectangle.
One benefit of the flat plate rectangular geometry is maximizing the surface area with a single catalyst structure using a monolith catalyst, as described later.
Returning to the description of the elongated conduit 302, referring to
The elongated conduit 302 can be manufactured from steel, stainless steel, any ferrous alloy, or combinations thereof
The elongated conduit 302 includes multiple stamped portions 324a. For example, as shown in
As shown in
Referring to
As shown in
In some embodiments, the catalytic structure 336, or each of the multiple catalytic structures 336a, 336b, and 336c are catalytic monoliths.
The catalytic structures 336a, 336b, and 336c can be assembled as modules (not shown) from smaller sub-units of coated monolith which are fitted into the frame of the modules. The modules can be configured in a variety of different shapes and sizes. In some embodiments, the modules can have the same shape as the interior portion of the conduit, for example a flattened profile (e.g., see catalytic structure 336 in
Alternatively or in addition, the catalytic structure 336, or each of the multiple catalytic structures 336a, 336b, and 336c are multiple catalyst pellets.
The catalytic structure 336 (and the multiple catalytic structures 336a, 336b, and 336c) is fixedly coupled to the elongated conduit 302. For example, the multiple catalytic structures 336a, 336b, and 336c can be fixedly coupled to the elongated conduit 302 by the multiple stamped portions 324a, 324b, and 324c as previously described. For example, as shown in
The catalytic structure 336 can generally include any active catalyst material (e.g., catalytic nanoparticles) supported on a substrate. For example, in some embodiments, catalytic structure 336 can include a catalyst formulation that is coated (e.g., wash-coated) on a substrate. In some embodiments, the catalyst formulation can be coated on the substrate directly or formed into particles or pellets. In some embodiments, the catalytic structure includes a catalyst formulation in the form of a washcoat, which is a high porosity ceramic material containing active catalyst metals. In some embodiments, the catalyst washcoat materials and substrates can optionally include adsorption materials, for example, zeolites.
The catalyst substrate can include pellets, a ceramic monolith, a metal monolith, or combinations thereof. In some embodiments, the catalytic structure can include a ceramic, metal, or combinations thereof. In some embodiments, the catalytic structure can include a ceramic material, including but not limited to, aluminum oxide, cerium oxide, zinc oxide, or the like. In some embodiments, the catalytic structure can include cordierite. In some embodiments, the catalytic structure can include a single active material, or a combination of multiple active materials.
The catalytic structure 336 can include one or more metals. In some embodiments, the catalytic structure can include stainless steel, for example, iron-chromium-aluminum alloys commercially known as Kanthal® or FeCrAlloy.
Referring to
In some embodiments, the catalyst reactor system 100 can be integrated into a simple-cycle gas turbine such that the need for tempering air is eliminated. The catalyst reactor system 100 can cause an ammonia decomposition reaction that cools the exhaust and reclaims waste energy. In various embodiments, both oxidation and SCR catalysts are present in the plant.
In some embodiments, the catalyst reactor system 100 can be arranged upstream of the oxidation and/or SCR catalyst. In some embodiments, the catalyst reactor system 100 upstream of the oxidation and/or SCR catalysts. While the catalysts provide a small increase in process temperature, in some embodiments, it may be advantageous to move the reactor to a location far upstream where temperatures are much higher (e.g., temperatures are significantly higher near the duct burner than near the SCR assembly). This would be especially useful if a lower activity catalyst was to be used. Process heat generated after the catalysts would still be recovered through non-catalytic preheating/vaporizing of the ammonia.
The plant 700 can include an oxidation catalyst assembly 708. In some embodiments, the oxidation catalyst assembly 708 can optionally use chemical heat provided by a selective catalytic reduction (SCR) catalyst to partially decompose ammonia to hydrogen and nitrogen at concentrations suitable for complete combustion.
The plant 700 can include an ammonia injection grid 710, substantially similar to the duct burner previously described. The catalyst reactor system 100 can be positioned in the enclosure 118 before the oxidation catalyst assembly 708 at location 712. The catalyst reactor system 100 can be positioned proximal (location 712) to an output of an oxidation catalyst assembly 708 of the heat recovery steam generator plant 800 such that a threshold quantity of heat is transferred from the oxidation catalyst assembly 708 to the catalyst reactor system 100.
The plant 700 can include a reduction catalyst assembly 716. Alternatively, the catalyst reactor system 100 can be positioned in the enclosure 118 after the reduction catalyst assembly 716 and the ammonia injection grid 710 at location 714. The catalyst reactor system 100 can be positioned proximal to an output of a reduction catalyst assembly 716 of the plant 700 such that a threshold quantity of heat is transferred from the reduction catalyst assembly 716 to the catalyst reactor system 100.
The plant 700 can include an exhaust stack 718. The exhaust stack 718 includes the outlet 122 previously described in reference to
The heat recovery steam generator plant 800 includes a selective catalytic reduction catalyst reactor 808. The catalyst reactor system 100 is positioned in the enclosure 118 after the first heat exchanger 802, the second heat exchanger 804, the third heat exchanger 806, and the selective catalytic reduction catalyst reactor 808.
The heat recovery steam generator plant 900 includes the selective catalytic reduction catalyst reactor 808. The catalyst reactor system 100 is positioned in the enclosure 118 after the first heat exchanger 802, the second heat exchanger 804, the third heat exchanger 806, but before the selective catalytic reduction catalyst reactor 808.
The natural gas combined heat and power plant 1100 includes a heat exchanger 1102. The heat exchanger 1102 is used for process heat recovery.
In some embodiments, as shown in
The control system 1302 includes a mixing/bypass conduit 1304. The mixing/bypass conduit 1304 can flow a portion of ammonia from the catalyst reactor system 100 and a portion of the hot expanded air/fuel mixture from the enclosure 118 directly to the duct burner 132.
The control system 1302 includes a mixing valve 1306. The mixing valve 1306 controls the flow of the portion of ammonia around the catalyst reactor system 100 to the duct burner 132.
The control system 1302 includes a metering valve 1308. The metering valve 1308 controls and measures the flow of the portion of ammonia from the catalyst reactor system 100 to the mixing valve 1306.
The control system 1302 can include one or more sensors. For example, in some embodiments, the control system 1302 can optionally include a first sensor 1310. The first sensor 1310 can be positioned within the system, for example, at or near the outlet 122. The first sensor 1310 can be configured to sense a quantity of residual ammonia in the exhaust stream. The first sensor 1310 can transmit a signal representing the quantity of ammonia in the outlet 122 to the mixing valve 1308. The mixing valve 1308 can actuate to increase or decrease the flow of the portion of ammonia from the catalyst reactor system 100 and the portion of the hot expanded air/fuel mixture from the enclosure 118 to the duct burner 132 in response to the sensed quantity of ammonia in the outlet 122.
The control system 1302 can optionally include a second sensor 1312. The second sensor 1310 can be positioned within the system, for example, at or near the outlet 122. The second sensor 1310 is configured to sense a quantity of oxides of nitrogen (NO/NO2) in the system (e.g., in the exhaust exiting through the outlet 122). In some embodiments, a system can dose ammonia into the exhaust to reduce NO/NO2, and dosing can be determined by online measurement of the NO/NO2 in the exhaust after SCR. The NO/NO2 in the exhaust can be measured periodically to effectively dose. In some embodiments, the systems provided herein can replace an ammonia dosing system by modulating the ammonia concentration by adjusting the amount of ammonia sent to a burner/turbine as compared to hydrogen from catalytic cracking. This control can be accomplished by a simple catalyst bypass valve. Unburned ammonia from a combustion device (e.g., a turbine) may result from excess ammonia being sent to the combustion device due to the ammonia's poor burning characteristics as compared to H2. In such circumstances, unburned ammonia would be present in the exhaust stream and used as reductant for the SCR.
The elongated conduit includes a wall defining an interior cavity and an exterior surface for transferring heat from the heat exchanging fluid to the interior cavity. The elongated housing includes an inlet for receiving a first fluid. The elongated housing includes an outlet to flow the first fluid out of the elongated conduit.
The elongated conduit has an interior cross-section defined by a major dimension and a minor dimension. The major and minor dimensions define an aspect ratio, α=W/H. The aspect ratio has a value greater than 1.071.
The catalyst reactor assembly includes a catalytic structure disposed within the interior cavity of the elongated conduit.
The catalyst reactor assembly is positioned within a reactor housing defining an enclosure. The housing includes a main inlet for receiving a heat exchanging fluid and a main outlet for flowing the heat exchanging fluid out of the housing.
At 1402, the heat exchanging fluid at a second temperature is received at the main inlet of the reactor housing.
At 1404, the heat exchanging fluid at the second temperature is flowed from the main inlet of the reactor housing to the first and second catalyst reactors.
At 1406, the heat exchanging fluid at the second temperature is received at the first and second catalyst reactors.
At 1408, the heat exchanging fluid is flowed to at least a portion of the exterior surfaces of the first and second catalyst reactors such that the heat exchanging fluid transfers heat to the first fluid across the walls of the conduits.
At 1410, the first fluid is heated to a third temperature such that the first fluid changes its composition.
Thermally decomposing ammonia using a thermochemical recuperator can further include flowing the heat exchanging fluid to the main outlet and exhausting the heat exchanging fluid to an atmosphere.
In some embodiments, the first fluid includes ammonia. The first fluid can be heated to a temperature that changes its composition, for example, by decomposing the first fluid (e.g., ammonia) or portions thereof as heat is transferred from a heat exchanging fluid to the first fluid. In some embodiments, the method can include flowing the heat exchanging fluid to at least a portion of the exterior surfaces of the first and second catalyst reactors such that the heat exchanging fluid transfers heat to the first fluid across the walls of the conduits. The flowing of the heat exchanging fluid can induce turbulence to occur in the heat exchanging fluid as the heat exchanging fluid flows to at least the portion of the exterior surfaces of the first and second catalyst reactors to increase the transfer of heat from the heat exchanging fluid to the first fluid.
While a number of examples have been described for illustration purposes, the foregoing description is not intended to limit the scope of the invention, which is defined by the scope of the appended claims. There are and will be other examples and modifications within the scope of the following claims. Furthermore, one of skill in the art would appreciate that features described in reference to a specific embodiment are not limited to that embodiment and can be interchanged with features of other embodiments.
This application claims the benefit of priority to U.S. Provisional Application Ser. No. 63/178,827, filed on Apr. 23, 2021. The disclosure of the prior application is considered part of and is incorporated by reference in its entirety into the disclosure of the present application.
Number | Date | Country | |
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63178827 | Apr 2021 | US |