JP2005147656A - Fuel diluting method and device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a method for reducing NOx by diluting fuel using a fuel diluting device. <P>SOLUTION: The fuel diluting device to be used in this method includes a first pipe line having an inlet and an outlet and fitted for sending a fuel flow entering from the inlet and outflowing from the outlet under a first thermodynamic state and a first fuel index; and a second pipe line having an intake and a discharge port, and fitted for sending a fluid flow entering from the intake and outflowing from the discharge port under a second/different thermodynamic state and a second fuel index different from the first fuel index by at least 0.1. This constitution produces a possibility of mixing two flows of outflowing from the outlet and the discharge port, at least, a part of the fuel is mixed with at least a part of the fluid near the outlet and the discharge port, and the second pipe line produces the diluted fuel flow having an intermediate fuel index. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

  The present invention relates to a fuel staging method and apparatus for reducing nitrogen oxide (NOx) emissions, and more particularly to such a method and apparatus utilizing a fuel dilution tip with a low NOx burner.

  One of the challenges facing the chemical process industry (CPI) is the combustion of waste fuel for economic reasons while simultaneously meeting low NOx and CO emission requirements. The waste fuel contains a mixture of gases with a high C / H ratio, which burn in a very bright flame due to the oxidation of carbon and also produce soot particles or carbon depending on the combustion process. Typical refinery fuel compositions contain varying amounts of fuel and inert gases (eg, C1, C2, C3 ... Cn, olefins, hydrogen, nitrogen, CO2, steam). When carbon or soot particles are formed on the fuel chip, soot structures typically grow under the convenient pressure and temperature conditions that exist near the tip exit. This can lead to fuel injection clogging, fuel injection distortion, overheating of chips and furnace components such as process tubes and fire walls, and potential burner and furnace shutdowns. If the furnace is shut down, significant financial penalties can be incurred, including the liability arising from downstream process interruptions.

Dirty refinery fuels with high carbon content and containing gases such as acetylene, ethane, propane, butane and olefins (eg, ethylene and propylene) generally produce soot particles when the fuel chip is exposed to: Generate.
Insufficient mixing in the furnace (depending on suboptimal injection number, injection configuration, injection angle and injection speed) (generally classified as a burner design issue),
• Lack of combustion air or oxidant available near the fuel outlet (generally classified as a burner flow configuration problem),
Inadequate cooling of the fuel tip (exposure to regular furnace radiation) (generally classified as a fuel tip configuration and burner design issue),
• Fuel flow obstruction (upstream fuel system reliability) (generally classified as a process problem)
• Lower combustion operation (low fuel flow due to process turndown) (generally classified as a process issue), or • Refinery fuel composition variation with respect to carbon-containing species (generally classified as a process requirements issue )

  The burner or tip design has a significant impact on tip overheating, soot formation, and tip clogging and, as a consequence, frequent burner equipment maintenance. These problems are exacerbated by changes in process conditions that affect the cooling required for the fuel tip, such as the lower end of the process turndown and / or fuel flow obstruction. Changes in process conditions and changes in fuel composition are common in refinery operations.

  Another challenge facing the CPI is the requirement for low NOx emissions to meet emissions regulations. In the United States, various areas where NOx regulations (under the Clean Air Act 1990) require NOx emissions from process heaters, boilers, gas turbines and other stationary combustion equipment to be less than 10 ppm. There is. The most common solution in CPI, or the BACT (best control technology available) solution, uses SCR (Selective Catalytic Reactor) to clean up the flue gas and within a large-scale catalytic reactor NOx contained in the flue gas stream is reduced using ammonia injection (by conversion of NOx to N2). This process is very capital intensive and requires large amounts of ammonia, hot air and electricity for ID fan operation.

  Most refineries want to avoid the installation of SCRs and instead want to use low NOx burners to meet NOx compliance requirements. However, low NOx burners do not consistently produce less than 10 ppm NOx in various process heating applications such as steam methane reformers (SMR), crude oil heaters, ethylene crackers or boilers. For this reason, the use of low NOx burners has not been recognized as BACT by regulatory authorities. In other words, SCR is currently the only commercially available solution that meets stringent NOx levels in areas where ozone reaches the ground, where ground-level ozone concentrations exceed legal limits.

  CPI operators typically use clean natural gas or an optimal mixture of natural gas and dirty refinery fuel to reduce the disadvantages of maintenance problems. However, due to the shortage of natural gas and high fuel costs, it is not always possible for the process industry to use clean natural gas for combustion. Refineries that can burn waste fuel are typically in a competitive position compared to other refineries that typically have high productivity and do not make full use of the potential of waste fuel.

  With respect to NOx reduction, a typical NOx control method involves utilizing a low NOx burner with high level fuel staging and air / fuel dilution with flue gas recirculation (FGR). By injecting non-reactive or inert species into the fuel / oxidant mixture, the average flame temperature is lowered, thus reducing NOx emissions. However, these methods require additional piping and energy costs for the transport of flue gas. Furthermore, there is an energy disadvantage because it is necessary to heat the gas from ambient temperature to process temperature. Moreover, field data published in the literature do not indicate that these methods achieve NOx performance below 10 ppm.

  Various devices and methods that utilize fuel staging have been developed for the purpose of reducing NOx emissions. Some of these are discussed below.

  US Patent Application No. 2003/0148236 (Joshi et al.) Discloses an ultra-low NOx burner that utilizes a staged fuel nozzle. This burner has eight fuel staging lances located around the main burner body. The center of the burner is used to supply 100% of the combustion air, and a very small amount of fuel (about 10%) is injected for the overall stability of the flame. The remaining fuel (about 90%) is injected using multiple fuel staging lances. The fuel staging lance has a special fuel nozzle tip with two circular holes. As shown in FIGS. 1A-1C, these lances are provided with combustion air and entrained furnace gas at relatively fast injection speeds (500-1,000 feet / second or 5-15 psig fuel supply pressure, depending on combustion speed). Due to the delayed mixing of both the axial and radial divergence angles.

  US Pat. No. 6,383,462 (Lang) discloses a method and apparatus having a mixing chamber outside the “burner and furnace” for mixing flue gas from the furnace with fuel gas as shown in FIG. Yes. Using a venturi mixer that shrinks and expands, the fuel gas is further diluted with additional flow induction gas. The resulting mixture (fuel diluted with flue gas) is then sent to a burner where it is mixed with combustion air and burned in a furnace. Depending on the dilution level of the flue gas, emissions of 26 to 14 ppm NOx can be reduced. This apparatus and method does not reduce NOx emissions below 10 ppm and the results are not comparable to those normally obtained with SCR technology.

  U.S. Pat. No. 6,481,209 (Johnson et al.) Discloses a fuel staging system suitable for a gas turbine engine. By dividing fuel injection into two stages: 1) an injector installed in a swirl mixer and 2) an injector installed in the trapped vortex region of the combustor, efficient combustion by air is achieved. Achieved with low NOx and CO emissions. However, this injection scheme is not suitable for large furnaces where a trapped vortex region is not possible due to the geometry of the furnace and load.

  US Pat. No. 6,558,154 (Eroglu et al.) Discloses a control system fuel staging scheme for aircraft engines that uses two separate instrumented fuel staging nozzles. A set of discharge and pulsation sensors is installed downstream of each staging area. These sensors measure the characteristics of the combustion products generated from each staging area, and then the control unit changes the relative amount of fuel injected into each area in response to changing operating and environmental conditions.

  US Pat. No. 5,601,424 (Bernstein et al.) Discloses a method for NOx reduction utilizing spray steam injection control. By adding spraying steam, available for spraying fuel oil, to the burner flame, the NOx level is reduced. A 30% reduction in NOx requires approximately 0.5 pounds of steam per pound of fuel flow. A large amount of steam is required to lower the flame temperature and obtain the required NOx reduction. In addition, when large amounts of steam are used to quench the flame, there is a possibility of flame instability and splashing. Therefore, there is an upper limit for steam injection for reasons of flame stability.

  The gas turbine industry is also using similar steam injection technology for NOx control. However, due to the inefficient steam injection method, great economic disadvantage is paid for reducing NOx emissions. Steam consumption is very high and this technique is relatively inefficient and cost-effective for NOx control.

US Patent Application No. 2003/0148236 US Pat. No. 6,383,462 US Pat. No. 6,481,209 US Pat. No. 6,558,154 US Pat. No. 5,601,424

  It would be desirable to have a cost-effective improved apparatus and method for reducing NOx emissions that provides the ability to burn refinery waste gas without excessive NOx emissions.

  It would be further desirable to have an apparatus and method that reduces equipment maintenance due to problems such as burner tip clogging and process tube overheating, and provides the added benefit of improved fuel efficiency and furnace productivity.

  Get equipment and methods that enable current low NOx burners to meet SCR-level NOx performance and allow refiners to comply with NOx regulations without capital intensive SCR technology It is further desirable.

  Enables the process industry to consume cheaper waste fuel without suffering from maintenance problems such as chip clogging, equipment overheating, process interruptions, etc., while simultaneously reducing NOx regulations by emitting less than 10 ppm of NOx It is further desirable to have an apparatus and method that can be satisfied.

  It would also be desirable to have a fuel combustion apparatus and method that provides better performance than the prior art and also overcomes many of the challenges and disadvantages of the prior art and provides better and more advantageous results.

  The present invention is a method and apparatus for diluting fuel and reducing nitrogen oxide emissions by fuel staging. The present invention also encompasses a fuel dilution device that can be used in the method or the apparatus.

  The first aspect of the method for diluting fuel and reducing nitrogen oxide emissions by fuel staging has multiple steps. The first step is to provide a fuel diluting device, which is a first conduit having an inlet and an outlet spaced from the inlet and entering from the inlet. A first line adapted to send a flow of fuel exiting the outlet at a thermodynamic state of 1 and a first fuel index; and a second line comprising an intake and the intake And a second conduit adapted to send a flow of fluid entering the inlet at a second thermodynamic condition and exiting the outlet at a second fuel index. The second fuel index is at least about 0.1 different from the first fuel index, and the second thermodynamic condition is different from the first thermodynamic condition, whereby the outlet of the first line There is a possibility of mixing the fuel flow exiting from the fluid flow exiting from the outlet of the second line. The second step is to supply a flow of fuel to the inlet of the first line, which flows from the outlet of the first line to the first thermodynamic state and the first fuel index. Get out. The third step is to supply a fluid flow to the inlet of the second conduit, which fluid flow from the outlet of the second conduit to the second thermodynamic state and the second At least a portion of the fuel flow exiting at the fuel index and thereby exiting from the outlet of the first conduit is at least a portion of the fluid flow exiting from the outlet of the second conduit and both the outlet and the outlet Mixing at a location proximate to the first fuel index, thereby producing at least one diluted fuel flow having an intermediate fuel index between the first fuel index and the second fuel index. The fourth step is to provide a source of oxidant. The fifth step combusts a portion of the oxidizer with at least a portion of at least one of the fuel stream, the fluid stream, or the diluted fuel stream, thereby reducing the amount of nitrogen oxides. Producing a reduced gas, the amount of nitrogen oxides being reduced being less than the amount of nitrogen oxides generated by burning the fuel using means other than the fuel diluter.

  There are many alternatives to the first aspect of the method. In one alternative, the fluid is a fuel. In another alternative, the fluid is selected from the group consisting of steam, flue gas, carbon dioxide, nitrogen, argon, helium, xenon, krypton, other inert fluids, and mixtures or combinations thereof.

In another alternative of the first aspect of the method, the first conduit is adjacent to the second conduit. In yet another alternative, at least a substantial portion of the second conduit is disposed within the first conduit. In yet another alternative, the second conduit has an equivalent diameter (D _c ) and the outlet of the second conduit is located at a distance behind the outlet of the first conduit. This distance ranges from about (2D _c ) to about (20D _c ).

  A second aspect of the method for diluting a fuel to reduce nitrogen oxide emissions by fuel staging is similar to the first aspect, but includes two additional steps. The first additional step is to provide a swirler that is placed in the second conduit. The second additional step is to send at least a portion of the fluid flow through the swirler, thereby swirling at least a portion of the fluid exiting the second conduit.

  The third aspect of the method is similar to the first aspect, but includes two additional steps. The first additional step is to provide a zipper nozzle that is in fluid communication with the outlet of the first conduit. The second additional step is to send at least a portion of the diluted fuel stream through the zipper nozzle.

  The fourth aspect of the method is similar to the first aspect, except that the fuel dilution device is placed in fluid communication with a furnace containing a predetermined amount of furnace gas, thereby providing the predetermined amount of heating. An additional step of mixing at least a portion of the furnace gas with at least a portion of the diluted fuel stream.

  Another embodiment of a method for diluting a fuel to reduce nitrogen oxide emissions by fuel staging includes multiple steps. The first step is to provide a fuel dilution device, which is a first conduit having an inlet and an outlet spaced from the inlet and entering from the inlet to a first pressure. A first line adapted to send a flow of fuel exiting the outlet at a first speed and a first fuel index; and a second line comprising an intake and the intake A second outlet adapted to deliver a flow of fluid entering the inlet and exiting the outlet at a second pressure, a second speed, and a second fuel index. A second fuel index is at least about 0.1 different from the first fuel index, and at least one of the second pressure and the second speed is at least one of the first pressure and the first speed. The flow of fuel exiting from the outlet of the first conduit and the fluid exiting from the outlet of the second conduit Re preparative there may be mixed. The second step is to supply a flow of fuel to the inlet of the first line, which flows from the outlet of the first line to the first pressure, the first speed, and the first. With a fuel index of The third step is to provide a fluid flow to the inlet of the second conduit, which fluid flow from the outlet of the second conduit is a second pressure, a second velocity, And at least a portion of the fuel flow exiting from the outlet of the first conduit, and at least a portion of the fluid flow exiting from the outlet of the second conduit; Mixing at a location proximate both of the outlets, thereby producing a flow of at least one diluted fuel having a fuel index intermediate between the first fuel index and the second fuel index. The fourth step is to provide a source of oxidant. The fifth step combusts a portion of the oxidizer with at least a portion of at least one of the fuel stream, the fluid stream, or the diluted fuel stream, thereby reducing the amount of nitrogen oxides. Producing a reduced gas, the amount of nitrogen oxides being reduced being less than the amount of nitrogen oxides generated by burning the fuel using means other than the fuel diluter.

  The first aspect of the fuel dilution apparatus for diluting the fuel and reducing the emission of nitrogen oxides by staging the fuel includes a plurality of components. The first component is a first conduit having an inlet and an outlet spaced from the inlet, the first conduit entering from the inlet and having a first thermodynamic state and a first It is suitable for sending the fuel flow exiting from the outlet with a fuel index of. The second component is a second conduit having an intake and an outlet spaced from the intake, the second conduit entering from the intake and a second thermodynamic Adapted to route a fluid flow exiting the outlet at a condition and a second fuel index, wherein the second fuel index differs from the first fuel index by at least about 0.1, and a second thermodynamic The condition is different from the first thermodynamic condition, whereby there is a possibility that the fuel flow exiting from the outlet of the first line and the fluid stream exiting from the outlet of the second line will mix. At least a portion of the flow of fuel exiting the outlet of the first conduit at a location proximate both the outlet and the outlet of at least a portion of the fluid flow exiting the outlet of the second conduit. Mixing, thereby an intermediate fuel index between the first fuel index and the second fuel index Causing at least one flow of the diluted fuel having. The third component is a source of oxidant. The fourth component combusts a portion of the oxidizer with at least a portion of at least one of the fuel stream, or the fluid stream, or the diluted fuel stream, thereby reducing the amount of nitrogen oxides. Is a means for producing a reduced gas, and this reduced amount of nitrogen oxides is greater than the amount of nitrogen oxides generated by burning the fuel using means other than the fuel dilution device. There are few.

  There are many other aspects of the first aspect of the fuel dilution device. In one alternative, the fluid is a fuel. In another alternative, the fluid is selected from the group consisting of steam, flue gas, carbon dioxide, nitrogen, argon, helium, xenon, krypton, other inert fluids and mixtures or combinations thereof.

In another alternative, the first conduit is adjacent to the second conduit. In yet another alternative, at least a substantial portion of the second conduit is disposed within the first conduit. In yet another alternative, the second conduit has an equivalent diameter (D _c ) and the outlet of the second conduit is located at a distance behind the outlet of the first conduit. This distance ranges from about (2 × D _c ) to about (20 × D _c ).

  In another alternative of the first aspect, the fuel dilution device is in fluid communication with a furnace containing a predetermined amount of furnace gas, whereby at least a portion of the amount of furnace gas is diluted as described above. Mixed with at least a portion of the fuel flow.

  A second aspect of the fuel dilution apparatus is similar to the first aspect, but includes a swirler disposed in the second conduit. A third aspect of the fuel dilution apparatus is similar to the first aspect, but includes a zipper nozzle in fluid communication with the outlet of the first conduit.

  Another embodiment of a fuel dilution apparatus for diluting fuel and reducing nitrogen oxide emissions by fuel staging includes a plurality of components. The first component is a first conduit having an inlet and an outlet spaced from the inlet, the first conduit entering from the inlet, a first pressure, a first velocity, and It is adapted to send a flow of fuel exiting the outlet at a first fuel index. The second component is a second conduit having an intake and a discharge opening spaced from the intake, the second conduit entering from the intake and a second pressure, Adapted to send a flow of fluid exiting the outlet at a speed of 2 and a second fuel index, wherein the second fuel index differs from the first fuel index by at least about 0.1, and the second fuel index At least one of the pressure and the second speed is different from at least one of the first pressure and the first speed, whereby the fuel flow exiting the outlet of the first line and the outlet of the second line There is a possibility that the fluid flow exiting from the at least one portion of the fuel flow exiting from the outlet of the first conduit and at least a portion of the fluid flow exiting from the outlet of the second conduit. Mixing at a location proximate to both the outlet and the outlet so that the first Causing at least one flow of the diluted fuel having an intermediate fuel index between the fuel index and the second fuel index. The third component is a source of oxidant. The fourth component combusts a portion of the oxidizer with at least a portion of at least one of the fuel stream, or the fluid stream, or the diluted fuel stream, thereby reducing the amount of nitrogen oxides. Is a means for producing a reduced gas, and this reduced amount of nitrogen oxides is greater than the amount of nitrogen oxides generated by burning the fuel using means other than the fuel dilution device. There are few.

  Another aspect of the present invention is a system for diluting fuel to reduce nitrogen oxide emissions by fuel staging. The system includes a plurality of components. The first component is a fuel diluter, which is a first line having an inlet and an outlet spaced from the inlet, and enters the inlet from the first thermodynamic state and A first conduit adapted to send a flow of fuel exiting the outlet at a fuel index of 1, a second conduit having an intake and an outlet spaced from the intake; A second conduit adapted to send a flow of fluid entering the inlet and exiting the outlet at a second thermodynamic condition and at a second fuel index, the second fuel index being a first And the second thermodynamic condition is different from the first thermodynamic condition so that the fuel flow exiting the outlet of the first line and the second thermodynamic condition are different from the first thermodynamic condition. There is a possibility of mixing the fluid flows exiting the duct outlet. The second component is a means for supplying a flow of fuel to the inlet of the first line, the flow of fuel from the outlet of the first line being in a first thermodynamic state and a second state. It goes out with a fuel index of 1. The third component is a means for supplying a fluid flow to the inlet of the second conduit, the fluid flow from the outlet of the second conduit to the second thermodynamic state. And at least a portion of the fuel flow exiting from the outlet of the first conduit and at least a portion of the fluid flow exiting from the outlet of the second conduit; And at a location proximate both the outlet, thereby producing at least one diluted fuel flow having a fuel index intermediate between the first fuel index and the second fuel index. The fourth component is a source of oxidant. The fifth component combusts a portion of the oxidizer with at least a portion of at least one of the fuel stream, the fluid stream, or the diluted fuel stream, thereby reducing the amount of nitrogen oxides. Is a means for producing a reduced gas, and this reduced amount of nitrogen oxides is greater than the amount of nitrogen oxides generated by burning the fuel using means other than the fuel dilution device. There are few.

  Another aspect of a system for diluting fuel and reducing nitrogen oxide emissions by fuel staging includes a plurality of components. The first component is a fuel diluter, which is a first line having an inlet and an outlet spaced from the inlet, entering from the inlet, a first pressure, a first speed, And a first conduit adapted to send a flow of fuel exiting the outlet at a first fuel index and a second conduit having an inlet and an outlet spaced from the inlet. A second line adapted to send a flow of fluid entering from the inlet and exiting the outlet at a second pressure, a second speed, and a second fuel index; The index is at least about 0.1 different from the first fuel index, and at least one of the second pressure and the second speed is different from at least one of the first pressure and the first speed, thereby The flow of fuel exiting from the outlet of one conduit and the fluid flow exiting from the outlet of the second conduit mix Potential exists. The second component is a means for supplying a flow of fuel to the inlet of the first line, the flow of fuel from the outlet of the first line being a first pressure, a first velocity. And the first fuel index. The third component is a means for supplying a fluid flow to the inlet of the second conduit, the fluid flow from the outlet of the second conduit to the second pressure, At least a portion of the flow of fuel exiting at the velocity and the second fuel index, thereby exiting from the outlet of the first conduit, and at least a portion of the fluid flow exiting from the outlet of the second conduit; Mixing at a location proximate both the outlet and the outlet thereby producing at least one diluted fuel flow having a fuel index intermediate between the first fuel index and the second fuel index. . The fourth component is a source of oxidant. The fifth component combusts a portion of the oxidizer with at least a portion of at least one of the fuel stream, the fluid stream, or the diluted fuel stream, thereby reducing the amount of nitrogen oxides. Is a means for producing a reduced gas, and this reduced amount of nitrogen oxides is greater than the amount of nitrogen oxides generated by burning the fuel using means other than the fuel dilution device. There are few.

  The present invention will now be described by way of example with reference to the accompanying drawings.

The present invention addresses several problems encountered in combustion equipment designs, such as reformers, process heaters, boilers, ethylene crackers or other burners used to heat high temperature furnaces. . The present invention relates to an improved fuel staging process. Specifically, depending on the required process objectives, two common approaches for rapid dilution and mixing are as follows.
1. Fuel staging with other fuels (FF). For clean, maintenance-free low NOx operation, high-pressure refinery waste fuel, sprayed liquid fuel, etc. are injected in the vicinity of a relatively clean low-pressure gaseous fuel.
2. Staging of fuel with inert gas (FI). In order to reduce NOx, a high-pressure inert fluid such as steam, nitrogen or CO2 is injected in the vicinity of the low-pressure gaseous fuel.

As used herein, the term “fuel index” (FI) is defined as the weighted sum of the number of fuel carbon atoms, the numerator H2 is assigned a carbon number of 1.3, and the weight is the mole fraction of the component. FI = ΣC _i x _i / Σx _i , where C _i and x _i are the number of carbon atoms and the mole fraction of component i, respectively. The fuel indices for several fuels and inert materials are listed in Table 1. In general, a fuel with a higher fuel index decomposes more easily and generates more NOx by a rapid NOx mechanism. H2 is a special case in this definition. Although H2 has no carbon atoms, it is well known that H2 addition to natural gas increases NOx emissions. The literature suggests that pure H2 flames emit about 30% more NOx than methane flames. The increase in NOx emissions from the H2 flame is due to the high flame temperature due to the thermal NOx mechanism. Here, since the fuel index is used as an index of NOx emission, a value of 1.3 is assigned to H2 so as to match the potential of NOx emission.

(1) ROG: H2 18%, CH4 44%, C2H2 38%.
(2) PSA offgas: H2 30%, CH4 18%, CO2 52%.
(3) Natural gas: CH4 91%, C2H6 4%, C3H8 3%, N2 1%, CO2 1%.
(4) Natural gas: CH4 84%, C2H6 12%, C3H8 2%, N2 2%.

  As discussed herein, the term “thermodynamic state” is defined as the state of presence of a substance. This definition is based on commonly known thermodynamic concepts, but not only normal temperature and pressure but also velocity, concentration, composition, volume fraction, flow rate, potential, etc. Has been extended to characterize. Using this definition, mixing is precisely defined as a result of the difference in the thermodynamic state of the two streams.

  Two approaches are discussed in detail below.

1. Fuel staging with another fuel (FF)
Using this approach, a high supply pressure refinery waste fuel containing a mixture of hydrogen and high C / H fuel (ethane, propane, butane, olefins, etc.) is converted into a second, relatively clean, low pressure fuel. Can be burned with gas. In such refinery waste fuels, maintenance problems arise due to pyrolysis of high C / H fuel and subsequent soot accumulation in the burner fuel chip. Moreover, combustion of such fuels causes more NOx emissions than usual.

  In order to improve the combustion of high C / H refinery waste fuel, this dirty fuel can be used as a relatively clean (secondary) fuel stream (eg hydrogen, synthesis gas, natural gas, or low BTU fuel). Dilute with blend). In one embodiment shown in FIG. 3, high pressure refinery fuel gas (containing a high C / H ratio fuel gas) is injected through a central lance 32, eg, natural gas, synthesis gas, process gas, PSA offgas. A relatively clean low pressure fuel gas, such as (recycled fuel gas after removal of product hydrogen from the PSA adsorbent bed), is injected through an annular region 33 between the center lance 32 and the outer lance 34. . As shown in FIG. 3, the center lance outlet 36 is recessed a preferred distance from the outer lance outlet 38. This distance is preferably 2 to 20 times the equivalent diameter (Dc) of the central lance. Depending on the fuel distribution between the high pressure refinery fuel gas and the cleaner low pressure fuel gas, the distance is preferably about 1/16 inch to 1 inch.

  Those skilled in the art will appreciate that referring to “high pressure” in FIGS. 3-7 and 9 is also referred to as “high speed” or “high pressure or high speed”. Similarly, referring to “low pressure” in the figures also means “low speed” or “low pressure or low speed”.

  The arrangement shown in FIG. 3 allows dirty high pressure refinery fuel gas to be mixed with cleaner low pressure fuel gas by turbulent jet interaction. The speed of the high pressure refinery fuel gas through the central lance 32 is preferably about 900-1400 feet / second (preferably sonic or choked speed). The velocity of the low pressure fuel gas through the annular region 33 between the center lance 32 and the outer lance 34 is preferably about 100 to 900 feet / second, depending on the available supply pressure of the low pressure gas. The high velocity gas stream exiting the central lance outlet 36 entrains the low velocity gas stream approaching the outer lance outlet 38 and mixes the “first stage” before the flow exits through the holes 40. Bring. The outer lance hole geometries, angles, etc. are designed for optimal “second stage” mixing in the furnace atmosphere. A very large amount of furnace gas 42 is entrained for the second stage dilution, thereby lowering the peak flame temperature and consequently reducing NOx emissions.

  FIG. 4 shows an arrangement for (FF) staging with liquid fuel. In this embodiment, high-pressure (and high C / H ratio) liquid fuel (for example, fuel oil, diesel, bunker C, waste liquid fuel, etc.) is diluted with low-pressure fuel gas and then into the furnace atmosphere. Further dilute by spraying. For example, heavy fuel oil can be sprayed with a spraying fluid such as steam and then diluted with low pressure fuel gas to provide a clean combustion in the furnace. This embodiment also reduces NOx emissions due to the lower peak flame temperature.

In FIG. 4, X is the distance from the outlet of the central lance 32 to the back of the outlet of the outer lance 34. D _c is the flow area equivalent diameter at the center lance outlet, ie the total flow area at the center lance outlet is the same as the circle of diameter D _c . D _e is the flow area-equivalent diameter of the outer lance, i.e. the total flow area of the lance outlet is the same as a circle of diameter D _e.

  Two other aspects of (F-F) staging are shown in FIGS. 5A and 5B. In FIG. 5A, a strong and weak injection interaction occurs between the high pressure refinery fuel gas and the low pressure fuel gas. The high pressure refinery fuel gas is injected into the high pressure lance 52 at a high speed (approximately 900-1400 feet / second) in the preferred direction, and the low pressure fuel gas injected into the low pressure lance 54 is entrained by the high pressure refinery fuel gas. The

  In FIG. 5B, the high pressure refinery fuel gas is swirled in the central lance 32 using the fuel swirler 56 and the low pressure fuel gas is entrained in the recessed region (central region) of the high speed swirl. This allows the high pressure refinery fuel gas and the low pressure fuel gas to mix well before leaving the outer lance 34 and into the furnace (not shown), where the furnace gas 42 Additional dilution by is performed. This approach is advantageous for applications that require a short flame profile or a smaller combustion space.

  (FF) Staging is typically utilized in a steam methane reformer (SMR) where high pressure fuel gas is supplied with natural gas or refinery off-gas, generally classified as trim fuel. . Referring to FIG. 6, the high pressure fuel gas is injected at the center lance 32. The low-pressure fuel gas injected into the annular region 33 between the central lance 32 and the outer lance 34 is generally off-gas of PSA (pressure swing adsorption), or CO2 (about 45%), hydrogen (about 30%), methane. A clean exhaust stream from a PSA with a fuel index of about 0.64 containing (about 15%) and CO (about 10%). The PSA off-gas is a permeate that emerges from the adsorbent bed after separation of the hydrogen product. High pressure trim fuel accounts for between 10% and 30% of the total energy of a typical reformer with PSA for hydrogen separation.

  A side benefit of this staging application is improved PSA recovery by increasing the PSA pressure cycle range, particularly on the lower end. With reference to FIG. 7, this is accomplished by creating a low pressure region in the outer lance 34. The central high speed injection 72 shown in FIG. 7 creates a low pressure region around the injection body where the slower moving low pressure fuel gas is entrained by the faster moving central injection. Due to the active entrainment process, the supply pressure of the low pressure fuel gas is reduced for the same fuel flow rate.

  In laboratory combustion experiments, the low gas PSA off-gas feed pressure was reduced from 2 psig to 1.6 psig (20% reduction). This was accomplished by injecting high pressure fuel gas at 25 psig (1300 ft / sec velocity). The distribution of combustion energy between the high pressure fuel gas and the low pressure fuel gas was 30:70, respectively.

In order to further quantify the details of the (F-F) staging process, laboratory test results were considered using a low NOx burner. The burner had 10 fuel lances distributed around a 18 inch diameter circle. Of the 10 fuel lances, two lances were reserved for the (FF) type staging arrangement. The lance had special fuel tips and a plurality of diverging slots (zipper tips 74) to improve passive mixing. A schematic diagram of the (F-F) fuel staging arrangement utilizing the zipper tip 74 is shown in FIG. The burner rating was designed to use two fuels with a combustion rate of 8 MMBtu / h utilizing air preheating of 644 ° F. Details of these two types of fuel are shown below.
High pressure refinery fuel gas: H2 (18%), natural gas (44%), and ethylene (38%). This fuel has a fuel index of 1.43, accounting for 30% of the total energy input.
Low pressure fuel gas: CO2 (52%), natural gas (18%), and H2 (30). It has a fuel index of 0.57, accounting for 70% of the total energy input.

  Referring to the arrangement shown in FIG. 7, a standard 3/8 inch diameter and 0.035 inch wall thickness concentrically placed in an outer lance 34 made of a 3/4 inch schedule 40 tube. A high-pressure fuel gas was injected into a central lance 32 made of pipe material. A zipper tip 74 was attached to the tip of the tube. The zipper tip was sized to have an equivalent diameter of 0.51 inches and had four vertical slots and one horizontal slot as shown in FIGS. As follows: 1) a series of vertical structures in a plane across adjacent main shapes, 2) downstream instabilities induced by flow, and 3) first fluid (fuel) and second fluid (heating) For the axial zipper nozzle tip geometry of high level molecular (small scale) mixing with furnace gas), the vertical slot opening angles (α1 and α2) were 18 ° and 6 °, respectively. The above mixing was also achieved with the shortest axial distance. A laboratory experiment of a low NOx burner using the lance inlance structure (including zipper tip) of FIG. 7 shows that the opening angle β is 7 °, rapid axial mixing, and more furnace gas entrainment. Indicated.

  As a result of the overall fluid process with the arrangement of FIG. 7, a more uniform heat transfer to the charge occurred at a fuel pressure of less than 2 psig, and very small amounts (<15 ppmv) of NOx and CO were discharged. Without the Lance Inlance process, high pressure and high C / H ratio fuels were also found to produce a noticeable sooted flame. Moreover, the NOx emission amount increased to about 25 to 30 ppm. This experiment showed that the FF staging process can dramatically reduce NOx emissions. In the FI staging process, the emissions could be further reduced by inert materials.

  Whenever the Lance Inlance (FF) fuel staging configuration is used for refinery fuels consisting of as much as 50% butane (C4H10), assisted mixing is visible in the laboratory furnace. Observed. Individual flames were found to mix much more rapidly with the furnace gas and resulted in wide spread or flameless combustion. On the other hand, a simple lance with a cylindrical nozzle lance gives a relatively long (blueish) relatively long flame, indicating less dilution and mixing of the furnace gas, while at the same fuel supply pressure. NOx and CO emission levels were relatively high.

  Table 2 shows the preferred combustion range, dimensions, dimensionless ratio and injection angle for the proposed lance inlance configuration. A simple circular tube was used for the high pressure refinery fuel, while a zipper tip was used for the low pressure PSA offgas fuel. These lances are an important component of low NOx burners because the reliability of the burner performance directly affects the steam methane reformer by flow performance.

  The above dimensional range is effective for various fuels such as natural gas, propane, refinery off-gas, and low BTU fuel. The nozzle is sized optimally depending on the fuel composition, flow rate (or combustion rate) and supply pressure available at the burner inlet. In Table 2, dimensions, ratios and ranges are estimated for burner burn rates of 2-10 MMBtu / h. However, these dimensions and ranges can be scaled up for higher burn rate burners (> 10 MMBtu / h) using standard engineering techniques to maintain a similar flow rate range.

2. Fuel staging with inert gas (FI)
Improved fuel staging with high pressure inert gas, such as steam (dry or saturated), CO2, flue gas, nitrogen or other inert gas, is performed using low pressure fuel gas to reduce NOx emissions. Staging fuels that can be used include, but are not limited to, natural gas, low BTU process gas (consisting of hydrogen and other refinery fuels), and PSA offgas. The structure of the injection tip is the same as that shown in FIGS. The main objective is to further reduce NOx emissions. A preferred embodiment is shown in FIG.

  Referring to FIG. 9, high pressure (30-100 psig) saturated or dry steam is sent through the central lance 32 at about 900-1400 feet / second, and low pressure fuel gas is in the annular region 33 between the central lance 32 and the outer lance 34. Sent through. High speed steam injection 92 entrains fuel gas for first stage dilution (and mixing) within the annular region. The resulting mixture is then zippered at high speed (approximately 600-1400 feet / second) for second stage dilution utilizing furnace gas (not shown) in a furnace (not shown). Exit through 74. This second stage dilution is very efficient due to the large steam velocity and the entrainment loop obtained by the individual flame formed by the zipper tip. Due to the zipper tip configuration and steam assistance, fuel dilution is improved. The peak flame temperature is further reduced, and NOx emissions are extremely reduced. Table 3 shows the estimated steam consumption for a large steam methane reformer furnace.

  As shown in Table 3, because of the unique method of fuel staging with an inert gas such as steam, the amount of steam required for fuel dilution is very small. (FI) The amount of steam required for staging is about 2% to 10% on a pound basis per pound when compared to low pressure fuel. Steam high speed is in two stages: 1) in the lance tube using steam and low pressure fuel gas, and 2) in the furnace space using high speed fuel-steam mixture and furnace gas. Used for the dilution process.

  From a laboratory experiment using an inert gas such as nitrogen, based on a comparison of a simple prior art lance structure (only a zipper or circular tip without a lance inlance configuration) and the lance inlance structure of FIG. It has been shown that NOx reduction of about 30% to 40% is possible. For example, using a low NOx burner with a combustion rate of 5 MMbtu / h, using ambient combustion air, a furnace operating at an average temperature of 1600 ° F, exhaust gas at 2000 ° F, and using a nitrogen flow rate of 10% by weight Then, NOx emission is reduced from about 10 ppm (corrected with 3% O 2) when there is no inert gas at the center to about 7 ppm (corrected with 3% O 2) when there is nitrogen gas at the center.

  In each of the aspects discussed above, the advantageous results achieved by the present invention are brought about by two differences in the flow exiting the two conduits. The first difference is the difference in the thermodynamic state of each flow, and the second difference is the difference in the fuel index of each flow. Specifically, in order for the two streams exiting the two pipelines to mix, there must be a difference in the thermodynamic state of the two streams, in order to significantly reduce NOx. There must be a difference of at least 0.1, preferably at least 0.2, between the fuel indices of the two streams.

  In the embodiment described graphically and discussed above, the difference between the thermodynamic states of the two flows is due to the pressure difference (ie, the “high pressure” fluid in one line and the “low pressure” fluid in the other line). It is represented. However, those skilled in the art will appreciate that the difference in thermodynamic state can be expressed in terms of velocity, temperature, concentration, composition, volume fraction, flow rate, potential, etc., and can be obtained as a result thereof.

  Accordingly, the present invention includes many other aspects and variations thereof not shown in the drawings or not discussed in the best mode for carrying out the invention. Nevertheless, such aspects and modifications are included in the scope of the matters described in the claims and in the scope of matters equivalent thereto.

  Those skilled in the art will also recognize that the modes and variations discussed in the best mode for carrying out the invention shown in the drawings do not disclose all possible configurations of the invention, and that other configurations are possible. Let's acknowledge that there is. Accordingly, all such other configurations are contemplated by and are within the scope of the invention. For example, in each of the embodiments described in FIGS. 3-7 and 9, the arrangement of the low pressure flow and the high pressure flow may be reversed (ie, the low pressure lance may be an inner lance and the high pressure lance may be an outer lance). ).

  In addition to reducing NOx emissions, the present invention has other advantages and benefits, some of which are discussed below.

  The proposed fuel staging method allows active chip cooling by either (F-F) staging or (FI) staging. In a fuel tip having a relatively large tip exit area, the nozzle tip is actively cooled by the flow of high-speed fuel gas or inert material that exits. This is a significant improvement over conventional circular nozzles.

Due to the relatively low entrainment efficiency and high operating temperature, the use of high C / H fuel presents significant maintenance problems and clogging problems with conventional chips. Compared to this, the present invention has the following advantages.
-Decreased tendency to coke while using fuel with higher carbon content.
-A fuel with a lower flow rate or higher heating value can be used.
-Less expensive fuel nozzle material (stainless steel 304 or 310 is appropriate) can be used.

  Pyrolysis is a major concern for many refinery furnaces where the fuel composition contains hydrocarbons in the C1-C4 range. The decomposed carbon clogs the burner nozzle, resulting in overheating of the burner parts, reduced productivity and insufficient thermal efficiency. Therefore, performing maintenance-free operation (using FF or FI staging) is an important advantage for refinery operators.

  Although illustrated and described herein with reference to specific embodiments, the present invention is nevertheless not limited to the details shown. Rather, various modifications can be made to the details within the scope of the appended claims and equivalents without departing from the spirit of the invention.

1 is a cross-sectional plan view of a prior art fuel staging nozzle used in an ultra low NOx burner. FIG. 1B is an elevational cross-sectional view of the prior art fuel staging nozzle of FIG. 1A. FIG. 1B is a side view of the prior art fuel staging nozzle of FIG. 1B. FIG. 1 is a front cross-sectional view of a prior art mixing chamber for mixing flue gas and flow induction gas from a heating furnace with fuel gas. FIG. 1 is a schematic cross-sectional view of one embodiment of the present invention. It is a schematic cross section of another aspect of the present invention. It is a schematic diagram explaining another aspect of this invention using the companion of strong injection and weak injection. FIG. 6 is a schematic cross-sectional view of another embodiment of the present invention that utilizes vortex induced entrainment. It is a schematic cross section of another aspect of the present invention. It is a schematic cross section of another aspect of this invention containing a zipper tip or a nozzle. It is a model front view of a zipper tip or a nozzle. 8 is a schematic side view of a zipper tip or nozzle attached to a lance, such as that shown in FIG. It is a model top view of a zipper tip or a nozzle. FIG. 8B is a schematic diagram detailing a portion of the front view of the zipper tip or nozzle of FIG. 8A for dimensioning. It is a schematic cross section of another aspect of this invention containing a zipper tip or a nozzle.

Explanation of symbols

32 Central lance 33 Annular region 34 Outer lance 36 Central lance outlet 38 Outer lance outlet 40 Hole 42 Furnace gas

Claims (22)

A method for diluting fuel to reduce nitrogen oxide emissions by fuel staging, comprising the following steps:
A step of providing a fuel dilution device, the fuel dilution device comprising:
A first conduit having an inlet and an outlet spaced apart from the inlet for delivering a flow of fuel that enters from the inlet and exits the outlet at a first thermodynamic condition and a first fuel index; A first conduit adapted to, and
A second conduit, having an inlet and an outlet spaced from the inlet, of fluid entering the inlet and exiting the outlet in a second thermodynamic state and a second fuel index A second conduit adapted to deliver a flow, wherein the second fuel index differs from the first fuel index by at least about 0.1, and the second thermodynamic state is the first thermodynamic A second line in which there is a possibility of mixing the flow of fuel exiting the outlet of the first line and the flow of fluid exiting the outlet of the second line,
A step of providing a fuel dilution device,
Supplying a flow of fuel exiting at a first thermodynamic state and a first fuel index from an outlet of the first line to an inlet of the first line;
Supplying a fluid flow to an inlet of a second conduit, the fluid flow exiting from the outlet of the second conduit at a second thermodynamic condition and a second fuel index. At least a portion of the flow of fuel exiting the outlet of the first conduit at a location proximate both the outlet and the outlet of at least a portion of the fluid flow exiting the outlet of the second conduit. Mixing fluid into the inlet of the second line, thereby producing a flow of at least one diluted fuel having a fuel index intermediate between the first fuel index and the second fuel index. Supplying a flow;
Providing a source of oxidant; and
A portion of the oxidant is combusted with at least a portion of at least one of the fuel stream, the fluid stream, or the diluted fuel stream, thereby using a means other than the fuel diluter. Producing a gas containing a reduced amount of nitrogen oxides less than the amount of nitrogen oxides generated by burning the fuel;
A fuel dilution method.   The method of claim 1, wherein the fluid is a fuel.   The method of claim 1, wherein the fluid is selected from the group consisting of steam, flue gas, carbon dioxide, nitrogen, argon, helium, xenon, krypton, other inert fluids, and mixtures or combinations thereof. .   The method of claim 1, wherein the first conduit is adjacent to the second conduit.   The method of claim 1, wherein at least a substantial portion of the second conduit is disposed within the first conduit. Providing a swirler disposed in the second conduit; and
Sending at least a portion of the fluid flow through the swirler, thereby swirling at least a portion of the fluid exiting the second conduit;
The method of claim 1, further comprising: Providing a zipper nozzle in fluid communication with the outlet of the first conduit; and
Sending at least a portion of the diluted fuel stream through the zipper nozzle;
The method of claim 1, further comprising: The second conduit has an equivalent diameter (D _c ) and the outlet of the second conduit is located at a distance behind the outlet of the first conduit, and this distance is approximately (2 × D The method of claim 1, which ranges from _c ) to about (20 × D _c ).   The fuel diluter is disposed in fluid communication with a furnace containing a predetermined amount of furnace gas so that at least a portion of the predetermined amount of furnace gas mixes with at least a portion of the diluted fuel stream. The method of claim 1, comprising a further step. A method for diluting fuel to reduce nitrogen oxide emissions by fuel staging, comprising the following steps:
A step of providing a fuel dilution device, the fuel dilution device comprising:
A first conduit having an inlet and an outlet spaced from the inlet, the flow of fuel entering from the inlet and exiting the outlet at a first pressure, a first velocity, and a first fuel index A first conduit adapted to send
A second conduit having an inlet and an outlet spaced from the inlet and entering from the inlet at a second pressure, second speed, and second fuel index from the outlet; A second conduit adapted to route the exiting fluid stream, wherein the second fuel index is at least about 0.1 different from the first fuel index and the second pressure and second speed At least one of the first pressure and the first velocity is different from at least one of the first pressure and the first velocity, whereby the flow of fuel exiting the outlet of the first line and the flow of fluid exiting the outlet of the second line A second conduit where there is a possibility of mixing,
A step of providing a fuel dilution device,
Supplying a flow of fuel exiting at a first pressure, a first speed, and a first fuel index from an outlet of the first line to an inlet of the first line;
Supplying a fluid flow to an inlet of a second conduit, the fluid flow from the outlet of the second conduit to a second pressure, a second velocity, and a second fuel index. So that at least a portion of the fuel flow exiting from the outlet of the first conduit is in proximity to at least a portion of the fluid flow exiting from the outlet of the second conduit and both the outlet and the outlet. A second line intake that produces at least one diluted fuel flow having an intermediate fuel index between the first fuel index and the second fuel index Supplying a fluid flow to
Providing a source of oxidant; and
A portion of the oxidant is combusted with at least a portion of at least one of the fuel stream, the fluid stream, or the diluted fuel stream, thereby using a means other than the fuel diluter. Producing a gas containing a reduced amount of nitrogen oxides less than the amount of nitrogen oxides generated by burning the fuel;
A fuel dilution method. A fuel dilution device for diluting fuel to reduce nitrogen oxide emissions by fuel staging,
A first conduit having an inlet and an outlet spaced from the inlet, adapted to send a flow of fuel entering from the inlet and exiting the outlet at a first thermodynamic condition and a first fuel index The first pipeline,
A second conduit having an inlet and an outlet spaced from the inlet, the flow of fluid entering the inlet and exiting the outlet in a second thermodynamic state and a second fuel index The second fuel index is at least about 0.1 different from the first fuel index and the second thermodynamic state is different from the first thermodynamic state; There is a possibility that the flow of fuel exiting from the outlet of the first conduit and the fluid flow exiting from the outlet of the second conduit will be mixed, so that the flow of fuel exiting from the outlet of the first conduit At least a portion of the fluid flow exiting the outlet of the second conduit and mixing at a location proximate to both the outlet and the outlet so that the first fuel index and the second At least one diluted fuel having a fuel index intermediate between the fuel indices Causing the flow, the second conduit,
A source of oxidant, and
A portion of the oxidant is combusted with at least a portion of at least one of the fuel stream, the fluid stream, or the diluted fuel stream, thereby using a means other than the fuel diluter. Means for producing a gas containing a reduced amount of nitrogen oxides less than the amount of nitrogen oxides generated by burning the fuel;
A fuel diluter.   The fuel dilution device according to claim 11, wherein the fluid is fuel.   12. The fuel of claim 11, wherein the fluid is selected from the group consisting of steam, flue gas, carbon dioxide, nitrogen, argon, helium, xenon, krypton, other inert fluids, and mixtures or combinations thereof. Dilution device.   The fuel dilution device according to claim 11, wherein the first pipe line is adjacent to the second pipe line.   The fuel dilution device of claim 11, wherein at least a substantial portion of the second conduit is disposed within the first conduit.   The fuel dilution device of claim 11, further comprising a swirler disposed in the second conduit.   The fuel dilution device of claim 11, further comprising a zipper nozzle in fluid communication with the outlet of the first conduit. The second conduit has an equivalent diameter (D _c ) and the outlet of the second conduit is located at a distance behind the outlet of the first conduit, and this distance is approximately (2 × D The fuel dilution device of claim 11, wherein the fuel dilution device ranges from _c ) to about (20 × D _c ).   The fuel dilution device is in fluid communication with a furnace containing a predetermined amount of furnace gas so that at least a portion of the predetermined amount of furnace gas mixes with at least a portion of the diluted fuel stream; The fuel dilution device according to claim 11. A fuel dilution device for diluting fuel to reduce nitrogen oxide emissions by fuel staging,
A first conduit having an inlet and an outlet spaced from the inlet for delivering a flow of fuel that enters the inlet and exits the outlet at a first pressure, a first speed, and a first fuel index; A first conduit adapted to
A second conduit having an inlet and an outlet spaced from the inlet, entering from the inlet and exiting the outlet at a second pressure, a second speed, and a second fuel index The second fuel index is at least about 0.1 different from the first fuel index, and at least one of the second pressure and the second speed is the first pressure, There is a possibility that the flow of fuel exiting from the outlet of the first line and the flow of fluid exiting from the outlet of the second line are mixed, differing from at least one of the first velocities; At least a portion of the fuel flow exiting from the outlet of the first conduit is mixed with at least a portion of the fluid flow exiting from the outlet of the second conduit at a location proximate both the outlet and the outlet. Thereby intermediate between the first fuel index and the second fuel index Create a flow of at least one diluted fuel having a fuel index, the second conduit,
A source of oxidant, and
A portion of the oxidant is combusted with at least a portion of at least one of the fuel stream, the fluid stream, or the diluted fuel stream, thereby using a means other than the fuel diluter. Means for producing a gas containing a reduced amount of nitrogen oxides less than the amount of nitrogen oxides generated by burning the fuel;
A fuel diluter. A system for diluting fuel and reducing nitrogen oxide emissions by fuel staging,
A first conduit having an inlet and an outlet spaced from the inlet, adapted to send a flow of fuel entering the inlet and exiting the outlet at a first thermodynamic state and a first fuel index A second conduit having an inlet and an outlet spaced from the intake, the second conduit entering from the inlet, the second thermodynamic state and the second A second conduit adapted to send a fluid flow exiting the outlet at the fuel index, wherein the second fuel index differs from the first fuel index by at least about 0.1, and the second fuel index The thermodynamic state is different from the first thermodynamic state, so that the flow of fuel exiting from the outlet of the first line and the flow of fluid exiting from the outlet of the second line may be mixed. There is a fuel dilution device,
Means for supplying a flow of fuel exiting from the outlet of the first conduit at a first thermodynamic condition and a first fuel index to the inlet of the first conduit;
Means for supplying a fluid flow to an inlet of a second conduit, the fluid flow from the outlet of the second conduit in a second thermodynamic state and a second fuel index. At least a portion of the flow of fuel exiting and exiting from the outlet of the first conduit is in proximity to at least a portion of the fluid flow exiting from the outlet of the second conduit and both the outlet and the outlet The fluid flow into the second tube, thereby producing at least one diluted fuel flow having an intermediate fuel index between the first fuel index and the second fuel index. Means for supplying to the intake of the road,
A source of oxidant, and
A portion of the oxidant is combusted with at least a portion of at least one of the fuel stream, the fluid stream, or the diluted fuel stream, thereby using a means other than the fuel diluter. Means for producing a gas containing a reduced amount of nitrogen oxides less than the amount of nitrogen oxides generated by burning the fuel;
Including a fuel dilution system. A system for diluting fuel and reducing nitrogen oxide emissions by fuel staging,
A first conduit having an inlet and an outlet spaced from the inlet, the flow of fuel entering the outlet and entering the outlet at a first pressure, a first speed, and a first fuel index; A second conduit having an inlet and an outlet spaced from the inlet, the second pressure entering the inlet and the second speed. And a second conduit adapted to route a fluid flow exiting the outlet at a second fuel index, wherein the second fuel index differs from the first fuel index by at least about 0.1 And at least one of the second pressure and the second velocity is different from at least one of the first pressure and the first velocity, whereby the flow of fuel exiting the outlet of the first conduit and the second velocity A fuel diluting device, in which there is a possibility of mixing of the fluid flow exiting the outlet of the pipe line,
Means for supplying a flow of fuel exiting from the outlet of the first line at a first pressure, a first speed, and a first fuel index to the inlet of the first line;
Means for supplying a fluid flow to an inlet of a second conduit, the fluid flow from the outlet of the second conduit at a second pressure, a second velocity, and a second At least a portion of the fuel flow exiting at the outlet of the first conduit, so that at least a portion of the fluid flow exiting from the outlet of the second conduit, and the outlet and outlet The fluid flow is mixed at a location proximate to both to thereby produce at least one diluted fuel flow having an intermediate fuel index between the first fuel index and the second fuel index. Means for feeding to the intake of the two conduits;
A source of oxidant, and
A portion of the oxidant is combusted with at least a portion of at least one of the fuel stream, the fluid stream, or the diluted fuel stream, thereby using a means other than the fuel diluter. Means for producing a gas containing a reduced amount of nitrogen oxides less than the amount of nitrogen oxides generated by burning the fuel;
Including a fuel dilution system.

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