This application relates to a compact premix fuel combustion system for the purpose of heat generation, methods of using a premix fuel combustion system, and methods of fluid heating incorporating a compact premix fuel combustion system.
Premix fuel combustion systems are used to provide a heated thermal transfer fluid for a variety of commercial, industrial, and domestic applications such as hydronic, steam, and thermal fluid boilers, for example. Because of the desire for improved energy efficiency, compactness, reliability, and cost reduction, there remains a need for improved premix fuel combustion systems, as well as improved methods of manufacture thereof.
Incomplete combustion, suboptimal combustion product flow fields, and large temperature gradients can result in a decrease in overall burner system performance. This is particularly true of combustion systems incorporated into fluid heating systems for the production of hot water, steam, and thermal fluid for hot liquid or steam for ambient temperature regulation, hot water consumption, or commercial and industrial applications. Moreover, residential, commercial, industrial and government uses of combustion systems for a variety of applications benefit from improvements that decrease the size, volume and footprint of these apparatuses, particularly those that utilize premix fuel and air (oxygen) combinations. Thus, there remains a need for an improved compact premix fuel combustion system having improved thermal efficiency.
Disclosed herein is an inward firing premix burner combustion system.
Also disclosed is an inward firing premix burner combustion system with a composite semi-cone combustion substrate.
Also disclosed is an inward firing premix burner combustion system with a composite semi-cone combustion substrate and a guide or baffle for directing the fuel-air mixture.
The above described and other features are exemplified by the following figures and detailed description.
Referring to the figures, which are exemplary embodiments, and wherein the like elements are numbered alike.
As further discussed herein, the Applicants have discovered that outward firing combustion systems can suffer incomplete combustion due to the small and constrained combustion volume available, large temperature gradients that can result in material and performance failures, and undesirable flow characteristics of the hot combustion gases and products can be produced in the apparatus.
Disclosed is an improved premix fuel combustion system for applications that require heat generation which provides improved efficiency, apparatus lifecycle and performance by alleviating or eliminating these disadvantages.
While not wanting to be bound by theory, the following nomenclature is useful in the detailed description that follows:
Consistent with convention, a cone is a geometric surface that can be used to describe certain aspects of embodiments of the present disclosure, e.g., a combustion surface or substrate (as discussed hereinafter).
For a semi-cone, the generator angle (alpha or α, as discussed further herein, e.g., regarding an angle of a combustion surface or substrate as described herein) is the angle 114 formed between a specific generator ray 116 and the axis 114 at the vertex 102. For a right circular semi-cone, right circular truncated cone or right circular frustum, all the generator angles are equal and a unique generator angle can be determined.
A semi-cone with a generator angle of ninety degrees (90°) is a flat plate, surface, disk or annulus and the limit of a family of semi-cones that share a common distal end dimensions and shape.
A burner is a combustion system designed to provide thermal energy through a combustion process to apparatuses used for a variety of applications. The burner may include, depending upon the fuel, combustion geometry and target application, a burner head that supports the combustion process, one or a plurality of nozzles or orifices, air blower with damper, burner control system, shut-off devices, fuel regulator, fuel filters, fuel pressure switches, air pressure switches, flame detector, ignition devices, air damper and fuel valves and fittings. Typical burner systems range in capacity from 30 kW to 1,500 kW (approximately 40 HP to 2,100 HP) and can be adapted to a wide range of uses including incinerators, boilers, drying systems, industrial ovens and furnaces.
A package burner is a burner combustion system designed to be incorporated as a standalone modular subsystem unit into apparatuses used for a variety of applications. The package burner may include, depending upon the fuel, combustion geometry and target application, an integrated subsystem comprising a burner head that supports the combustion process, one or a plurality of nozzles or orifices, air blower with damper, burner control system, shut-off devices, fuel regulator, fuel filters, fuel pressure switches, air pressure switches, flame detector, ignition devices, air damper and fuel valves and fittings. Typical package burner systems range in capacity from 30 kW to 1,500 kW (approximately 40 HP to 2,100 HP) and can be adapted to a wide range of uses including incinerators, boilers, drying systems, industrial ovens & furnaces.
In the discussion that follows, we distinguish three types of physical combustion mechanisms. First, “volume combustion” occurs where a fuel-air mixture is ignited in a spatial volume. A physical structure may contain the combustion process, such as in a cavity burner, but the details of the structure do not directly participate in the thermodynamic combustion process. Second, for “surface combustion”, the combustion process (or a majority thereof) occurs directly upon—or very near, or largely in contact with—a burner combustion surface. In some cases, some form of physical insulating or separation layer may be needed at the burner surface to ensure the burner surface does not get too hot or to provide otherwise needed separation from the surface. The physical, geometrical and material characteristics of the surface contribute to determining the thermodynamic physics. Third, in “suspended flame combustion” (SF combustion), the combustion process (or a majority thereof) occurs near—but not directly on—the surface of a combustion substrate, which provides physical support for the generation of the flame front. In some conditions, a small portion of the flame may contact the burner surface (as described more hereinafter). In SF combustion, the flame front (or a majority thereof) is suspended near a positional equilibrium at a distance from the substrate determined partly by a balance of opposing forces due to fuel-air mass flow and flame migration toward its fuel source. If the fuel-air mass flow is reduced below a threshold, the flame front can approach the substrate and enter a regime of surface combustion. If the fuel-air mass flow is increased above a threshold, the flame front can enter a regime of volume combustion.
A boiler is a fluid heating system incorporating a heat exchanger that may be used to exchange heat between any suitable fluids, e.g., a first fluid and the second fluid, wherein the first and second fluids may each independently be a gas or a liquid. In the disclosed system, the first fluid, which is directed through the heat exchanger core, is a thermal transfer fluid, and may be a combustion gas, e.g., a gas produced by fuel fired combustor, and may comprise water, carbon monoxide, nitrogen, oxygen, carbon dioxide, combustion byproducts or combination thereof. The thermal transfer fluid may be a product of combustion from a hydrocarbon fuel such as natural gas, propane, or diesel, for example.
Also, the second fluid, which is directed through the pressure vessel and contacts an entire outer surface of the heat exchanger core, is a production fluid and may comprise water, steam, oil, a thermal fluid (e.g., a thermal oil), or combination thereof. The thermal fluid may comprise water, a C2 to C30 glycol such as ethylene glycol, a unsubstituted or substituted C1 to C30 hydrocarbon such as mineral oil or a halogenated C1 to C30 hydrocarbon wherein the halogenated hydrocarbon may optionally be further substituted, a molten salt such as a molten salt comprising potassium nitrate, sodium nitrate, lithium nitrate, or a combination thereof, a silicone, or a combination thereof. Representative halogenated hydrocarbons include 1,1,1,2-tetrafluoroethane, pentafluoroethane, difluoroethane, 1,3,3,3-tetrafluoropropene, and 2,3,3,3-tetrafluoropropene, e.g., chlorofluorocarbons (CFCs) such as a halogenated fluorocarbon (HFC), a halogenated chlorofluorocarbon (HCFC), a perfluorocarbon (PFC), or a combination thereof. The hydrocarbon may be a substituted or unsubstituted aliphatic hydrocarbon, a substituted or unsubstituted alicyclic hydrocarbon, or a combination thereof. Commercially available examples include Therminol® VP-1, (Solutia Inc.), Diphyl® DT (Bayer A. G.), Dowtherm® A (Dow Chemical) and Therm® S300 (Nippon Steel). The thermal fluid can be formulated from an alkaline organic compound, an inorganic compound, or a combination thereof. Also, the thermal fluid may be used in a diluted form, for example with a concentration ranging from 3 weight percent to 10 weight percent, wherein the concentration is determined based on a weight percent of the non-water contents of the thermal transfer fluid in a total content of the thermal transfer fluid.
An embodiment in which the thermal transfer fluid comprises predominately gaseous products from combustion of natural gas or propane, and further comprises liquid water, steam, or a combination thereof and the production fluid comprises liquid water, steam, a thermal fluid, or a combination thereof is specifically mentioned.
A jet burner is a type of (non-premix) burner combustion system wherein fuel is ejected from one or a plurality of orifices or nozzles, and the lean or partially oxygenated fuel is ignited to produce a flame.
Disclosed in
The flame 200 produced by the ignited fuel jet stream is a rotating structure 236 and can extend in length Lf a significant distance in the furnace 230 cavity. An example of a jet burner combustion system is the Fulton 40-60 Horsepower LONOX® Burner where the flame may be two-to-four feet (0.6 to 1.2 meters) in length and occupy over half the length of the furnace 230.
Moreover, the jet burner embodiment of
Second, to achieve the higher pressure required at the burner head, both the air stream 210 and the lean 212 and rich 216 fuel flows must be maintained at relatively high pressures. That is, a significant fraction of the fan power used to drive these flows must be expended to overcome the pressure drops from the air 226, lean fuel 214 and rich fuel 218 conduits to the burner head 222 and maintain a relative high flow velocity.
Third, the mixing of the lean fuel 214 and rich fuel 218 flow streams with the air flow 204 is primarily generated by the flow of the fuels through small orifices in the burner head 222. Low turndown ratios consequently imply a reduction in fuel-air mixing, which can increase the production of incomplete combustion byproducts and undesirable emissions (e.g., NOx). Hence, the requirement for higher air and fuel flow velocities imposes limitations on low power operation, durability, lifecycle, maintenance requirements and emission characteristics.
The long flame length characteristic of a jet burner flame can be mitigated by using a porous substrate to support the flame, breaking the single long flame structure into many small flames concentrated in a compact region.
In a shell- and tube boiler heat exchanger application, the hot combustion products flow into the body of the furnace 230A where they pass through the heat exchanger tubesheet 302 and into the heat exchanger tubes 300. Thermal energy generated by combustion of the premix fuel-air mixture in the region of the composite flame 304 is transferred across the thin walls of the heat exchanger tubes 300 to the production fluid inside the pressure vessel 322 sealed at one end to the furnace by the top head 228A.
One disadvantage to the outward firing geometry is that the composite flame region 304 and hot combustion products 306 can impinge upon the inner surface of the furnace 230A, depending upon the fuel-air mass flow through the pores, the dimensions of the space between the burner combustion substrate 318 and the inner furnace wall 203A. Furthermore, the geometry of outward firing burners removes a substantial volume from the furnace cavity, reducing the volume available for combustion. As a result of the reduced volume, incomplete combustion occurs which lowers efficiency and increases the production of incomplete combustion products, including environmental contaminates.
Moreover, the flow of hot combustion products is guided by the relative geometry of the burner combustion substrate 318 and the furnace 230A cavity.
In what follows, we define the term “inward-firing” to be a configuration wherein the combustion flame structure is oriented along the pre-mix flow streamlines substantially towards the interior of the furnace volume or cavity. Furthermore, the flame structure may be supported by a “convex” substrate wherein the substrate creates a volume extending outward from the furnace cavity, or “concave” wherein the substrate forms a volume extending into the furnace cavity. For example,
The inventors have unexpectedly discovered that an inward-firing burner geometry alleviates many of the disadvantages described above.
α=arctan[(Dd−Dp)/H] Eq. 1
Dimensions of the combustion substrate depend upon the burner power, capacity, performance and size requirements of a specific application. Proximal diameters (Dp) between 1 inch and 59 inches is specifically mentioned. Distal diameters (Dd) between 2 inches and 60 inches is specifically mentioned. Substrate height (H) between 1 inch and 60 inches is specifically mentioned.
In some embodiments, the region of the cone circumscribed by the proximal edge 505 may be open (no endcap) or closed by an endcap, also shown in
The semi-cone sections of the burner combustion substrate angle may have any suitable generator angle between 1 degree, 2 degrees, 3 degrees, 4 degrees, 5 degrees, 10 degrees to 11 degrees, 12 degrees, 13 degrees, 14 degrees, 15 degrees, 16 degrees, 17 degrees, 18 degrees, 19 degrees, 20 degrees, 21 degrees, 22 degrees, 23 degrees, 24 degrees, 25 degrees, 26 degrees, 27 degrees, 28 degrees, 29 degrees, 30 degrees, 31 degrees, 32 degrees, 33 degrees, 34 degrees, 35 degrees, 36 degrees, 37 degrees, 38 degrees, 39 degrees, 40 degrees, 50 degrees, 60 degrees, 70 degrees, 80 degrees, 85 degrees, and 90 degrees wherein the foregoing upper and lower bounds can be independently combined. For the right circular semi-cone, right circular truncated cone, and the right circular frustum, the burner combustion substrate angles between 18 degrees and 35 degrees is specifically mentioned. For the right circular semi-cone, right circular truncated cone, and the right circular frustum, the burner combustion substrate angle of 25 degrees is also specifically mentioned.
In some embodiments, a burner combustion substrate angle α may be 90 degrees which corresponds to a flat structure, surface, plate, disk or annulus, which may be viewed as a degenerate semi-cone that is the limit of a family of semi-cones with diameter, Dd. For the right circular semi-cone, right circular truncated cone, and the right circular frustum, the burner combustion substrate angle α=90 degrees is specifically mentioned.
The burner combustion substrate is porous to the flow of premix fuel-air mixtures predominately in a vapor state. Substrate pores 506 are distributed over the area of the burner combustion substrate to support a flame front in the burner combustion cavity 635 near the interior surface. (The pore 512 size in a local area 510 are exaggerated in the diagram for clarity and are not meant to be to scale.) The combustion process may be monitored by a sensor 308A which can detect if the flame is extinguished.
In the embodiment shown a premix(ed) fuel-air mixture 514 enters the inlet 504 of the burner and flows within a burner pre-combustion cavity 631 and around and through the burner combustion substrate 500 inward toward the longitudinal (or axial) axis 509. The fuel-air mixture ratio is arranged so that the premix fuel is ignited near the interior surface to form a flame structure suspended over the interior surface of the burner combustion substrate, within a burner combustion cavity 635.
The flame structure may comprise individual flamelets—relatively small, distinct and stable laminar regions of combustion—which may merge at higher combustion production conditions and may form a flame front suspended a predetermined distance the substrate as described below.
In a boiler application comprising a shell and tube heat exchanger, the combustion products (e.g., hot gases, particulate byproducts) flow 518 towards the tubesheet 302B where they pass through the openings 300B of the heat exchanger tubes 508. Heat generated by the combustion process is transferred across the walls of the heat exchanger tubes 508 to production fluid occupying the space between the outer surfaces of the furnace 230C and heat exchanger tubes 508 and the inner surface of the pressure vessel 322A, sealed at one end by the boiler top head 228C.
Without being bound by theory, the burner combustion substrate provides a physical structure to support the flame front generated when the premix fuel-air mixture is ignited, and the porosity of the substrate determines certain aspects of the resulting combustion process as illustrated in
The tendency for the reaction zone to consume the premix fuel-air mixture creates a force toward the pore that tends to move the combustion interface 604 near its apex over the pore with a velocity vgnormal 608. Thus, these two opposing forces balance at a condition where the flame equilibrium ratio number:
where, in a time-average sense and the right inequality means “less than approximately”, denoting the fact that the upper bound has been empirically determined by practical examples and should not be construed to limit or constrain the interpretation of the claims. Other embodiments may possess practical upper bounds that are higher or lower when designed by those skilled in the art. That is, an important design characteristic is to select burner substrate construction, porosity and operation conditions that ensures the flame reaction zone remains approximately stationary relative to the pore opening suspended at a distance from the pore.
For certain combinations of pore geometry, which may be referred to herein as the “suspended flamelet” or “suspended flame” state, premix flow rate and operating conditions, the preheating zone 603, combustion interface 604 and reaction zone 605 remain attached 609 to edges of the pore 512A, forming a stable, persistent structure called a flamelet anchored to the interior surface of the burner substrate 601. Because the flamelet's preheating zone 603 contains uncombusted fuel-air mixture, it is relatively cool compares to the reaction zone 605. That is, the preheating zone 603 serves to insulate the substrate from the high temperature of the reaction zone 605. This is a desirable condition since it allows for high burner heat production capacity while simultaneously maintaining cooler temperatures at the burner substrate surface that promotes longevity of the substrate and reduces the likelihood of material failure. The separation of the reaction zone 605 from the substrate 601 inner surface that promotes this insulative effect can be expressed—in a local sense—as the flamelet separation distance, dSFL, 610 from the inner surface of the substrate 601 over the pore 512A and the apex of the combustion interface 604. In practice, flamelet separation distances for premixtures of natural gas and air are between zero (0) inches (surface combustion) and approximately 1.75 inches (suspended flame combustion, SF), although the distance will vary (stochastically and as an average distance observed over relatively long time periods) in practice. In some embodiments, the flamelets may overlap depending on the distance between pores, flow rate, and other conditions.
Under certain operating conditions, which may be referred to herein as the “suspended flame front” state, particularly when the premix fuel-air mixture flow velocity is high, the flamelets may detach from the inner surface of the burner substrate, as illustrated in the embodiment shown in
The conditions or states described herein with
These principles have been verified using an experimental test apparatus. Based on experimental data, Table 1 shows typical geometry and operating conditions that will exhibit suspended flame (SF) combustion in a burner using a semi-cone substrate geometry.
Porosity of the burner combustion substrate can be achieved by a number of constructive means, so long as they equivalently achieve and maintain the semi-conical shape and porosity characteristics required by a specific set of design parameters. Perforations in a solid substrate, including perforations in a metal sheet, are specifically mentioned.
The pore 2-dimensional and 3-dimensional structure, together with the distribution of pores in the burner combustion substrate, are designed in concert to achieve an operational flame structure required to meet the specifications a particular application.
The shapes and distributions of pores can be mixed to produce desirable heat production, pressure drop across the cross-section of the substrate and combustion stability properties as illustrated by the embodiment shown in
There are several important advantages to the arrangements in the disclosed embodiments. A first feature is that—depending upon the specific parametric choices for design parameters (including pore size and density, the fuel-air flow velocity and combustion substrate geometry)—while the burner can be operated in a range of combustion modes from surface combustion to volume combustion, the geometry is suitable for stable suspended flame (SF) combustion applications. This is desirable since the resulting separation distance between the flame front and the combustion substrate in SFF combustion: (a) relaxes the material demands on the substrate in the presence of high temperatures during operation, eliminating the need for insulation of the substrate; and, (b) reduces the risk of substrate material failure or contamination of the pores by combustion byproducts.
A second feature is that the semi-cone combustion substrate geometry promotes substantial uniformity of the combustion process over the entire interior surface of the substrate.
Moreover, the burner combustion substrate defines a combustion volume delineated by the interior surface of the substrate that is optimized for improved and complete combustion of the premix fuel-air mixture, homogeneous distribution of the flame front on the interior surface of the porous substrate (equivalently, diffuser), and substantial uniformity of the resulting flow field of combustion products.
The desirable flow field and temperature distribution properties persist for a range of semi-cone burner substrate geometries.
A third feature is that, even when the fuel-air mass flow rate is increased into the volume combustion regime, the semi-cone geometry alters the cavity flame structure so that the power density is increased, and a smaller flame is require to achieve a prescribed level of heat generation. Because the fuel-air mass flow is equally distributed over the surface of the porous combustion substrate, when driven into a volume combustion regime the entire length of the flame is equally impinged by the premix fuel. Hence, the structure of the body of the flame—normally divided into cool and hot regions—is altered to produce a hotter, more efficient combustion process. As a result, the same heat generation capacity is achieved by a smaller flame size with higher power density, and more complete combustion can occur in a smaller burner cavity.
Moreover, these beneficial aspects may be enhanced by guided control of the fuel-air flow field as it impinged on the outer surface of the combustion substrate. Disclosed are embodiments that further comprise a baffle or guide designed to distribute the incoming fuel-air mixture so that the local mass flow and velocity is close to (or substantially) uniform over the burner combustion substrate.
This embodiment further comprises a flow guide or baffle 700, between the walls of the burner casing 706. In this embodiment the baffle is an unperforated, non-porous substrate in the shape of a semi-cone with a non-planar proximal edge 702 and a planar, circular distal edge 704, disposed between the burner head 503A and the inner furnace 230D wall. Most of the premix fuel-air mixture 514A entering the burner inlet 504A impinges upon the baffle 708 so that the high-velocity flow doesn't disproportionately impinge upon the combustion substrate immediately adjacent to the inlet opening. Instead, the premix fuel-air flow is primarily directed around the outside of the baffle between the baffle 700 and the burner casing 706. The baffle proximal edge is shaped to that the fuel-air flow spills over the baffle proximal edge 702, passes 710 through burner combustion substrate pores 512A, and is ignited to form a combustion flame 516A since, by design, the premix fuel-air mixture is in the correct ratio to support ignition at the operating temperature and pressure. At the beginning of burner operation, combustion can also be initiated by a spark from an igniter 502A.
In a boiler application comprising a shell and tube heat exchanger, the combustion products (e.g., hot gases, particulate byproducts) flow towards the tubesheet 302C where they pass through the openings 300C of the heat exchanger tubes. Heat generated by the combustion process is transferred across the walls of the heat exchanger tubes to production fluid occupying the space between the outer surfaces of the furnace 230D and heat exchanger tubes and the inner surface of the pressure vessel 322B, sealed at one end by the boiler top head 228D.
A flow baffle 700A guides the fuel-air mixture flow between baffle and the walls of the burner casing 706A. As before, in this embodiment the baffle is an unperforated, non-porous substrate in the shape of a semi-cone with a non-planar proximal edge 702A and a planar, circular distal edge 704A, disposed between the burner head 503B and the inner furnace 230E wall. Most of the premix fuel-air mixture 514B entering the burner inlet 504B impinges 708A upon the baffle so that the high-velocity flow doesn't disproportionately impinge upon the combustion substrate immediately adjacent to the inlet opening. Instead, the premix fuel-air flow is primarily directed around the outside of the baffle between the baffle 700A and the burner casing 706A. The baffle proximal edge is shaped to that the fuel-air flow spills over the baffle proximal edge 702A, and passes 710A through burner combustion substrate pores 512B.
In a boiler application comprising a shell and tube heat exchanger, the combustion products (e.g., hot gases, particulate byproducts) flow towards the tubesheet 302D where they pass through the openings 300D of the heat exchanger tubes 508A. Heat generated by the combustion process is transferred across the walls of the heat exchanger tubes to production fluid occupying the space between the outer surfaces of the furnace 230E and heat exchanger tubes 508A and the inner surface of the pressure vessel 322C, sealed at one end by the boiler top head 228E.
Thus, a fourth aspect is that the semi-cone combustion substrate geometry promotes substantial homogeneity and substantial uniformity of the flow field exiting the burner casing. This is particularly important in apparatus comprising heat-generating burners for fluid heating applications utilizing, for example, shell-and-tube heat exchangers. Referring to
Towards this end, in certain embodiments a composite semi-cone combustion substrate is used when optimization of the combustion flow field over the height, H, requires a change in the local generator angle (alternatively, range of generator angles in the case of a general semi-cone). Otherwise, when optimization of the combustion flow field can be achieved using a single semi-cone, a semi-cone, truncated cone or frustum shape may be used.
A fifth feature is that substantially uniform combustion over the surface of the substrate and uniformity of the flow field exiting the burner contributes to an increase in thermodynamic efficiency of the combustion system. A result of the substantially uniform flow field and temperature distribution of combustion products generated by the premix burner comprising a composite semi-cone combustion substrate is an increase in overall system thermodynamic efficiency. This is a particularly important result for applications like fluid heating where energy efficiency and reduction of environmentally hazardous byproducts are key.
The inventors have also unexpectedly discovered that a plurality of concentric porous combustion porous surfaces or substrates, which may be collectively referred to herein as the “substrate”, can have a beneficial effect on the substantial uniformity of the fuel-air mixture velocity as it enters the interior of the burner combustion volume. Any number of layers or porous structures may be used if desired to make up the substrate provided they provide the porosity to provide the performance and function described herein.
Both the first 1400 and second 1402 burner combustion substrates are porous to the flow of premix fuel-air mixtures predominately in a vapor state. Pores 1404 are distributed over the area of the burner combustion substrate to support a flame front on the interior surface of the first burner combustion substrate. (The pore 512C size in a local area 510F are exaggerated in the diagram for clarity and are not meant to be to scale.) The combustion process may be monitored by a sensor 308D which can detect if the flame is extinguished. At startup, combustion may be initiated using an igniter 502C disposed in the interior of the first burner combustion substrate.
In the embodiment shown a premix fuel-air mixture enters the inlet 504H of the burner and flows around and through the burner combustion substrate inward to the interior of the burner combustion substrate.
In a boiler application comprising a shell and tube heat exchanger, the combustion products (e.g., hot gases, particulate byproducts) flow towards the tubesheet 302E where they pass through the openings 300EB of the heat exchanger tubes 508B. Heat generated by the combustion process is transferred across the walls of the heat exchanger tubes 508B to production fluid occupying the space between the outer surfaces of the furnace 230H and heat exchanger tubes 508B and the inner surface of the pressure vessel 322D, sealed at one end by the boiler top head 228F.
The various components of the premix fuel burner combustion system can each independently comprise any suitable material. Use of a metal is specifically mentioned. Representative metals include iron, aluminum, magnesium, titanium, nickel, cobalt, zinc, silver, copper, and an alloy comprising at least one of the foregoing. Representative metals include carbon steel, mild steel, cast iron, wrought iron, a stainless steel such as a 300 series stainless steel or a 400 series stainless steel, e.g., 304, 316, or 439 stainless steel, Monel, Inconel, bronze, and brass. Specifically mentioned is an embodiment in which the premix fuel burner combustion system components each comprise steel, specifically stainless steel. The premix burner combustion system may comprise a burner head, a combustion substrate, a baffle, a furnace wall that can each independently comprise any suitable material. Use of a steel, such as mild steel or stainless steel this mentioned. While not wanting to be bound by theory, it is understood that use of stainless steel in the dynamic components can help to keep the components below their respective fatigue limits, potentially eliminating fatigue failure as a failure mechanism, and promote efficient heat exchange.
A sixth feature is that of a flat substrate (annular substrate with Dd and Dp prescribed) is the geometrical limit of a sequence of semi-cone combustion substrate configurations within the inventive species sharing a common furnace diameter.
A family of semi-cone substrates sharing a common finance diameter (e.g., Dd in
The principles and characteristics of an embodiment similar to that shown in
The embodiment test results demonstrate the burner with a combustion substrate angle of ninety degrees (flat substrate) and a regular pattern of slots exhibits stable suspended flame combustion over a wide range of premix fuel-air mixture flow rates, substrate surface loading and heat production conditions.
There are equivalent methods for disposing the burner combustion substrate on the furnace structure.
The design of the perforation pattern, dimensions and distributions are separate inventive concepts from the semi-cone substrate structure, and the resulting flow and temperature properties can be exploited in various distinct configurations. For example,
Table 3 display test data collected on a prototype burner corresponding to the configuration shown in
Note that the pressure drop (difference between the fan outlet pressure and the furnace inlet pressure) across the burner is only 1.5 inches, which is more than 40% improvement over conventional burner technology. Also, the measured nitrous oxide (NOx) level is below 20 ppm at low oxygen feed rates (19.9 ppm NOx at 4.90%), and the permeability is about 60%.
As described above, the combustion substrate perimeter can be of any suitable shape that is convenient to manufacture and meets the dimension and functional requirements of the burner system.
Another feature of the combustion substrate geometry contemplated herein is a crease or ridge or fold in the surface of the substrate that is convenient to manufacture and meets the dimension and functional requirements of the burner system.
The pore distribution pattern need not be uniformly distributed on the surface of the combustion substrate.
A seventh feature is that the dimensions of the combustion substrate can be chosen such that, when a solution exists, the substrate fits within the overall physical constraints of the burner system while simultaneously providing a surface area for combustion support (loading) to provide a target burner heat production capacity. That is, achieving a prescribed burner heat production capacity requires a resulting range of available substrate surface area to support the combustion flame front. The designer skilled in the art of burner design can use the geometrical properties of the combustion substrate to achieve a target surface area for flame front loading while simultaneously achieving a compact configuration that fits within the physical dimension required by the furnace dimensions.
This feature can be illustrated using the geometry shown in
Using the combustion semi-cone combustion substrate dimensions shown in Table 1 for illustration,
The inventors have also unexpectedly discovered that an inward-firing burner geometry using a composite semi-cone mesh diffuser alleviates many of the disadvantages known for mesh burners, particularly when operated in the surface combustion regime.
α=arctan[(Dd−Dp)/H] Eq. 6
Dimensions of the combustion substrate 213 and metal fiber mesh 2032 depend upon the burner power, capacity, performance and size requirements of a specific application. Proximal diameters (Dp) between 1 inch and 59 inches is specifically mentioned. Distal diameters (Dd) between 2 inches and 60 inches is specifically mentioned. Substrate height (H) between 1 inch and 60 inches is specifically mentioned.
The semi-cone sections of the burner combustion substrate angle may have any suitable generator angle between 1 degree, 2 degrees, 3 degrees, 4 degrees, 5 degrees, 10 degrees to 11 degrees, 12 degrees, 13 degrees, 14 degrees, 15 degrees, 16 degrees, 17 degrees, 18 degrees, 19 degrees, 20 degrees, 21 degrees, 22 degrees, 23 degrees, 24 degrees, 25 degrees, 26 degrees, 27 degrees, 28 degrees, 29 degrees, 30 degrees, 31 degrees, 32 degrees, 33 degrees, 34 degrees, 35 degrees, 36 degrees, 37 degrees, 38 degrees, 39 degrees, 40 degrees, 50 degrees, 60 degrees, 70 degrees, 80 degrees, and 85 degrees wherein the foregoing upper and lower bounds can be independently combined. For the right circular semi-cone, right circular truncated cone, and the right circular frustum, the burner combustion substrate angles between 18 degrees and 35 degrees is specifically mentioned. For the right circular semi-cone, right circular truncated cone, and the right circular frustum, the burner combustion substrate angle of 25 degrees is also specifically mentioned.
The burner combustion substrate is porous to the flow of premix fuel-air mixtures predominately in a vapor state. Substrate pores 2012 are distributed over the area of the burner combustion substrate 2013. The combustion process may be monitored by a sensor 2004 which can detect if the flame is extinguished.
In the embodiment shown, a premix(ed) fuel-air mixture 2010 enters the inlet 2038 of the burner and flows 2022 within a burner pre-combustion cavity 2017 and around and through the burner combustion substrate 213 inward toward the longitudinal axis 2016. The fuel-air mixture 2010 ratio is arranged so that the premix fuel is ignited 2020 within the burner combustion cavity 2018.
In a boiler application comprising a shell and tube heat exchanger, the combustion products (e.g., hot gases, particulate byproducts) flow 2020 towards the tubesheet 2024 where they pass through the openings 2028 of the heat exchanger tubes 2026. Heat generated by the combustion process is transferred across the walls of the heat exchanger tubes 2026 to production fluid occupying the space between the outer surfaces of the furnace 2030 and heat exchanger tubes 2026 and the inner surface of the pressure vessel 2014, sealed at one end by the boiler top head 2008.
The metal fiber mesh can be of any type or construction. Woven metal fiber (warp and weave construction), knitted, sintering techniques are all specifically mentioned, as are equivalent methods. Final mesh fabric thickness can be between 0.05″ to 0.30″, with the threads forming the mesh being between 0.005 to 0.1. The threads, if used can be made from fibers which are 0.0005 to 0.005″. If sintered metal mesh is used, fibers which are 0.0005 to 0.005″ can be used to create the sintered mat. Joining the mesh with itself, or affixing it to a metal substrate is typically done using electric resistance spot welding, with multiple spot welds done in series to create a continuous seam where required for strength and durability.
If an insufficient amount of diffuser (layered substrate and mesh) area is dimensioned, the flame can lift off of the mesh surface and extinguish. This is one key advantage of cavity or cone burners; the high blow off threshold condition supports flame stability in both surface and SF combustion and, as a result, can potentially reduce the amount of surface area needed in comparison with other alternatives, thereby enhancing compactness of the apparatus and reduce material requirements in the manufacturing process.
There are several important advantages to the arrangements in the disclosed embodiments incorporating a mesh diffuser. A first aspect of the embodiment incorporating a mesh diffuser is that the mesh insulation layer enables the premix fuel-air burner combustion system to be operated in the “surface combustion” regime where the mass flow rate through the diffuser is low. In the absence of a mesh insulating layer, the close proximity of the flame front to the substrate can result in excessively high temperatures of the substrate, which can lead to thermal stresses and material failure. Additionally, these high temperatures can ultimately exceed autoignition temperature for premixed fuel and air, resulting the flame igniting behind the substrate, causing combustion in the annular region between the burner casing and substrate.
A second aspect of the embodiment incorporating a mesh diffuser is that the metal fiber mesh distributes and homogenizes the premix fuel-air flow stream emanating through the substrate pores or perforations, and contributes to a more uniform distribution of fuel on the combustion diffuser surface. Moreover, the mesh serves to further direct the passage of the premix fuel-air flow stream so that it emerges close to orthogonal to the inner diffuser surface (also called flow stratification), further creating a uniform fuel stream for the surface combustion process.
A third aspect of the embodiment incorporating a mesh diffuser is that the action of the metal fiber mesh to distribute and direct the premix fuel-air mixture to produce a uniform flow field for surface combustion reduces the risk of flashback. That is, it reduces the risk that the flame front locally migrates from the interior combustion surface, through the pores in the substrate, and into the annular region between the burner casing and the substrate.
A fourth aspect of the embodiment incorporating a mesh diffuser is that fine control of the delivery of the premix fuel-air to the interior of the burner cavity, or the burner combustion cavity, by the metal fiber mesh implies that the pores or perforations in the combustion substrate can be coarser and less uniform than if the substrate pores were solely responsible for the diffusion of the fuel mixture. Thus, the incorporation of the metal fiber mesh disposed on the inner substrate surface relaxes the manufacturing requirements and tolerances for the combustion substrate, reducing cost and enabling a broader range of usable materials and fabrication methods.
For example, conventional fabrication methods that stamp or punch holes in sheet metal to for the combustion substrate in a uniform pattern may produce a non-uniform radial pattern in a semi-cone element. This would be problematic if the substrate is used alone since it would result in a non-uniform radial distribution of premix fuel-air to the combustion process. (More flow where the pores are larger or denser; less flow in directions where the pores are smaller or sparser.) However, the addition of the metal fiber mesh layer serves to redistribute the flow evenly through the uniform mesh openings.
A fifth aspect of the embodiment incorporating a mesh diffuser is that in some embodiments where the premix fuel-air mixture is generated by injecting fuel into an air stream before it reaches the burner inlet conduit 238, the mesh helps provides additional mixing through the turbulent action of the fuel stream passing through the mesh openings. Thus, the metal fiber mesh contributes to the creation of a well-mixed lean fuel-air stream before it is ignited in the surface combustion process.
The various components of the premix fuel burner combustion system can each independently comprise any suitable material. Use of a metal is specifically mentioned. Representative metals include iron, aluminum, magnesium, titanium, nickel, cobalt, zinc, silver, copper, and an alloy comprising at least one of the foregoing. Representative metals include carbon steel, mild steel, cast iron, wrought iron, a stainless steel such as a 300 series stainless steel or a 400 series stainless steel, e.g., 304, 316, or 439 stainless steel, Monel, Inconel, bronze, and brass. Specifically mentioned is an embodiment in which the premix fuel burner combustion system components each comprise steel, specifically stainless steel. The premix burner combustion system may comprise a burner head, a combustion substrate, a baffle, a furnace wall that can each independently comprise any suitable material. Use of a steel, such as mild steel or stainless steel this mentioned. While not wanting to be bound by theory, it is understood that use of stainless steel in the dynamic components can help to keep the components below their respective fatigue limits, potentially eliminating fatigue failure as a failure mechanism, and promote efficient heat exchange.
The disclosed system can alternately comprise, consist of, or consist essentially of, any appropriate components herein disclosed. The disclosed system can additionally be substantially free of any components or materials used in the prior art that are not necessary to the achievement of the function and/or objectives of the present disclosure.
Further disclosed is a premix burner comprising: a burner casing with an inlet conduit for a premix fuel-air mixture to be disposed in the burner casing; a porous burner combustion substrate disposed in the burner casing wherein a premix fuel-air mixture enters the inlet conduit on an outside (exterior) of the burner combustion substrate. A premix fuel-air mixture is disposed under pressure through the burner inlet to an outside of the porous burner combustion substrate; passes through pores in the burner combustion substrate to an interior of the substrate; the fuel-air mixture is ignited in the interior of the burner combustion substrate; combustion gases and products flow from the interior of the burner combustion substrate through an outlet in the burner casing.
Further disclosed is the premix burner of Embodiment A, wherein the porous burner combustion substrate has the shape of a cylinder.
Further disclosed is the premix burner of Embodiment A, wherein the porous burner combustion substrate has the shape of a composite semi-cone.
Further disclosed is the premix burner of Embodiment A, wherein the porous burner combustion substrate has the shape of a semi-cone.
Further disclosed is the premix burner of Embodiment A, wherein the porous burner combustion substrate has the shape of a truncated cone.
Further disclosed is the premix burner of Embodiment A, wherein the porous burner combustion substrate has the shape of a circular truncated cone.
Further disclosed is the premix burner of Embodiment A, wherein the porous burner combustion substrate has the shape of a right circular truncated cone.
Further disclosed is the premix burner of Embodiment A, wherein the porous burner combustion substrate has the shape of a frustum.
Further disclosed is the premix burner of Embodiment A, wherein the porous burner combustion substrate has the shape of a circular frustum.
Further disclosed is the premix burner of Embodiment A, wherein the porous burner combustion substrate has the shape of a right circular frustum.
Further disclosed is the premix burner of any of Embodiments A to J, further comprising a plurality of burner casing inlets disposed on the burner casing.
Further disclosed is a premix burner of any of the Embodiments A to K, wherein the semi-cone generator angle is ninety degrees.
Further disclosed is a premix burner comprising: a burner casing with an inlet conduit for a premix fuel-air mixture to be disposed in the burner casing; a porous burner combustion substrate disposed in the burner casing; a metal fiber mesh disposed on the interior surface of the combustion substrate; wherein a premix fuel-air mixture enters the inlet conduit on an outside (exterior) of the burner combustion substrate. A premix fuel-air mixture is disposed under pressure through the burner inlet to an outside of the porous burner combustion substrate; passes through pores in the burner combustion substrate and through the pores of the metal fiber mesh to an interior of the diffuser; the fuel-air mixture is ignited in the interior of the burner combustion substrate; combustion gases and products flow from the interior of the burner cavity through an outlet in the burner casing.
Further disclosed is the premix burner of Embodiment M, wherein the porous burner combustion substrate and metal fiber mesh has the shape of a cylinder.
Further disclosed is the premix burner of Embodiment M, wherein the porous burner combustion substrate and metal fiber mesh has the shape of a composite semi-cone.
Further disclosed is the premix burner of Embodiment M, wherein the porous burner combustion substrate and metal fiber mesh has the shape of a semi-cone.
Further disclosed is the premix burner of Embodiment M, wherein the porous burner combustion substrate and metal fiber mesh has the shape of a truncated cone.
Further disclosed is the premix burner of Embodiment M, wherein the porous burner combustion substrate and metal fiber mesh has the shape of a circular truncated cone.
Further disclosed is the premix burner of Embodiment M, wherein the porous burner combustion substrate and metal fiber mesh has the shape of a right circular truncated cone.
Further disclosed is the premix burner of Embodiment M, wherein the porous burner combustion substrate and metal fiber mesh has the shape of a frustum.
Further disclosed is the premix burner of Embodiment M, wherein the porous burner combustion substrate and metal fiber mesh has the shape of a circular frustum.
Further disclosed is the premix burner of Embodiment M, wherein the porous burner combustion substrate and metal fiber mesh has the shape of a right circular frustum.
Further disclosed is the premix burner of any of Embodiments M to V, further comprising a plurality of burner casing inlets disposed on the burner casing.
An inward-firing surface combustion burner, comprising: a burner casing configured to receive a fuel-air mixture at a burner inlet and to provide hot combustion gas at a burner output; a combustion substrate disposed within the burner casing, the substrate having a shape comprising at least a semi-cone, having a substrate angle measured from a longitudinal axis, having a substrate porosity defined by a plurality of pores, and having a substrate inner surface and a substrate outer surface; a mesh disposed on the inner surface of the combustion substrate; the substrate configured to receive the fuel-air mixture at the outer surface of the substrate, the fuel-air mixture passing through the pores of the substrate and through the pores of the mesh at a mixture flow rate from the substrate outer surface toward the substrate inner surface; the burner configured such that, in operation, the fuel-air mixture ignites directly upon or largely in contact with the plurality of pores of the mesh.
The burner of Embodiment X, wherein the substrate angle has a range of values from 1 degree to 89 degrees.
The burner of Embodiment X, wherein a volume of the burner casing, a proximal diameter (Dp) of the substrate, a distal diameter (Dd) of the substrate, and a semi-cone angle of the substrate, are set such that the mixture rate is substantially uniform along a length of the substrate and forms a substantially uniform flame front along the inner surface of the substrate.
The burner of Embodiment X, wherein the surface combustion process provides a substantially uniform temperature distribution across the substrate inner surface and provides a substantially uniform flow field distribution of the hot combustion gas at the burner output.
The burner of Embodiment X, wherein the substrate comprises a plurality of porous layers to create the substrate porosity.
The burner of Embodiment X, wherein the shape of the substrate comprises at least one of: cone, semi-cone, composite semi-cone, truncated cone, frustum, right frustum, right circular truncated cone, and a right circular frustum.
The burner of Embodiment X, wherein the pores have a shape comprising at least one of: circular, rectangular, symmetrical shape, and asymmetrical shape.
The burner of Embodiment X, further comprising an ignitor disposed on an inner side of the substrate where the surface combustion occurs.
The burner of Embodiment X, wherein the combustion substrate comprises a proximal diameter (Dp) about 1 to 59 inches, a distal diameter (Dd) between 1 and 60 inches, a substrate height (H) between 1 and 60 inches, and a substrate angle between 1 degree and 89 degrees.
An inward-firing surface combustion burner, comprising: a burner casing configured to receive a fuel-air mixture at a burner inlet and to provide hot combustion gas at a burner output; a combustion substrate disposed within the burner casing, the substrate having a shape comprising at least a semi-cone, having a substrate angle measured from a longitudinal axis, having a substrate porosity defined by a plurality of pores, and having a substrate inner surface and a substrate outer surface; a mesh disposed on the inner surface of the combustion substrate; the substrate configured to receive the fuel-air mixture at the outer surface of the substrate, the fuel-air mixture passing through the pores of the substrate and through the pores of the mesh at a mixture flow rate from the substrate outer surface toward the substrate inner surface; the burner configured such that, in operation, the fuel-air mixture ignites directly upon or largely in contact with the plurality of pores of the mesh, such that surface combustion occurs.
Further disclosed is a hydronic fluid heating system (equivalently, a “hydronic boiler”) comprising a premix combustion system of any of Embodiments A to GG or elsewhere disclosed in this specification.
Further disclosed is a steam fluid heating system (equivalently, a “steam boiler”) comprising a premix combustion system of any of Embodiments A to GG or elsewhere disclosed in this specification.
Further disclosed is a thermal fluid heating system (equivalently, a “thermal fluid boiler”) comprising a premix combustion system of any of Embodiments A to GG or elsewhere disclosed in this specification.
Further disclosed is a packaged burner comprising a premix combustion system of any of Embodiments A to GG or elsewhere disclosed in this specification.
The disclosed system can alternately comprise, consist of, or consist essentially of, any appropriate components herein disclosed. The disclosed system can additionally be substantially free of any components or materials used in the prior art that are not necessary to the achievement of the function and/or objectives of the present disclosure.
The terms “a” and “an” do not denote a limitation of quantity, but rather denote the presence of at least one of the referenced item. The term “or” means “and/or” unless clearly indicated otherwise by context. Reference throughout the specification to “an embodiment”, “another embodiment”, “some embodiments”, and so forth, means that a particular element (e.g., feature, structure, step, or characteristic) described in connection with the embodiment is included in at least one embodiment described herein, and may or may not be present in other embodiments. In addition, it is to be understood that the described elements may be combined in any suitable manner in the various embodiments. “Optional” or “optionally” means that the subsequently described event or circumstance may or may not occur, and that the description includes instances where the event occurs and instances where it does not. The terms “first,” “second,” and the like, “primary,” “secondary,” and the like, as used herein do not denote any order, quantity, or importance, but rather are used to distinguish one element from another. The terms “front”, “back”, “bottom”, and/or “top” are used herein, unless otherwise noted, merely for convenience of description, and are not limited to any one position or spatial orientation.
The endpoints of all ranges directed to the same component or property are inclusive of the endpoints, are independently combinable, and include all intermediate points. For example, ranges of “up to 25 N/m, or more specifically 5 to 20 N/m” are inclusive of the endpoints and all intermediate values of the ranges of “5 to 25 N/m,” such as 10 to 23 N/m.
Unless defined otherwise, technical and scientific terms used herein have the same meaning as is commonly understood by one of skill in the art to which this invention belongs.
All cited patents, patent applications, and other references are incorporated herein by reference in their entirety. However, if a term in the present application contradicts or conflicts with a term in the incorporated reference, the term from the present application takes precedence over the conflicting term from the incorporated reference.
As will be recognized by those of ordinary skill in the pertinent art, numerous modifications and substitutions can be made to the above-described embodiments of the present disclosure without departing from the scope of the disclosure. Accordingly, the preceding portion of this specification is to be taken in an illustrative, as opposed to a limiting, sense.
Although the disclosure has been described herein using exemplary techniques, algorithms, or processes for implementing the present disclosure, it should be understood by those skilled in the art that other techniques, algorithms and processes or other combinations and sequences of the techniques, algorithms and processes described herein may be used or performed that achieve the same function(s) and result(s) described herein and which are included within the scope of the present disclosure. In addition, unless otherwise recited herein, any embodiment disclosed herein may be used with any other embodiment disclosed herein.
Any process descriptions, steps, or blocks in process or logic flow diagrams provided herein indicate one potential implementation, do not imply a fixed order, and alternate implementations are included within the scope of the preferred embodiments of the systems and methods described herein in which functions or steps may be deleted or performed out of order from that shown or discussed, including substantially concurrently or in reverse order, depending on the functionality involved, as would be understood by those reasonably skilled in the art.
It is noted that the Figures are to be taken as an illustrative example only, and are not to scale.
All cited references are incorporated in their entirety to the extent needed to understand the present disclosure, and to the extent permitted by applicable law.
It should be understood that, unless otherwise explicitly or implicitly indicated herein, any of the features, characteristics, alternatives or modifications described regarding a particular embodiment herein may also be applied, used, or incorporated with any other embodiment described herein.
Conditional language, such as, among others, “can,” “could,” “might,” or “may,” unless specifically stated otherwise, or otherwise understood within the context as used, is generally intended to convey that certain embodiments could include, but do not require, certain features, elements, or steps. Thus, such conditional language is not generally intended to imply that features, elements, or steps are in any way required for one or more embodiments or that one or more embodiments necessarily include logic for deciding, with or without user input or prompting, whether these features, elements, or steps are included or are to be performed in any particular embodiment.
Although the invention has been described and illustrated with respect to exemplary embodiments thereof, the foregoing and various other additions and omissions may be made therein and thereto without departing from the spirit and scope of the present disclosure.
This application is a continuation-in-part of U.S. patent application Ser. No. 16/285,119, filed on Feb. 25, 2019, which claims priority to U.S. Provisional Patent Application Ser. No. 62/634,476, filed on Feb. 23, 2018 and U.S. Provisional Patent Application Ser. No. 62/634,520, filed on Feb. 23, 2018, and this application claims priority to PCT Patent Application Serial No. PCT/US2019/019441, filed on Feb. 25, 2019, which claims priority to U.S. Provisional Patent Application Ser. No. 62/634,520, filed on Feb. 23, 2018, the contents of each application cited above are incorporated herein by reference in their entirety to the extent permissible by applicable law.
Number | Name | Date | Kind |
---|---|---|---|
3122197 | Saponara et al. | Feb 1964 | A |
3881869 | Neti et al. | May 1975 | A |
3947233 | Sundberg | Mar 1976 | A |
5380192 | Hamos | Jan 1995 | A |
6575736 | Aust et al. | Jun 2003 | B1 |
6612295 | Lerner | Sep 2003 | B2 |
9121604 | Min | Sep 2015 | B2 |
10539326 | Karkow | Jan 2020 | B2 |
20060251998 | Lamberts et al. | Nov 2006 | A1 |
20090032012 | von Herrmann et al. | Feb 2009 | A1 |
20130280662 | Dreizler et al. | Oct 2013 | A1 |
20190293285 | Nett | Sep 2019 | A1 |
20190353345 | Folkers | Nov 2019 | A1 |
20190363316 | Lee | Nov 2019 | A1 |
20200386400 | Nett et al. | Dec 2020 | A1 |
Number | Date | Country | |
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20200386400 A1 | Dec 2020 | US |
Number | Date | Country | |
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62634476 | Feb 2018 | US | |
62634520 | Feb 2018 | US |
Number | Date | Country | |
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Parent | 16285119 | Feb 2019 | US |
Child | 17001230 | US | |
Parent | PCT/US2019/019441 | Feb 2019 | US |
Child | 16285119 | US |