The present disclosure relates to burners, such as a superadiabatic burner.
Certain features and advantages of the disclosed subject matter are described in the appended claims. Additional features and advantages will be apparent to the person of ordinary skill in the art as this specification proceeds.
In one embodiment, a superadiabatic burner comprises a flame holder formed from a porous medium, a fuel inlet coupled to the flame holder, a fuel outlet coupled to the flame holder, a preheater comprising an inlet and an outlet coupled to the fuel inlet, and a radiating rod coupled to the porous medium. The porous medium comprises a first porous section and a second porous section.
In other embodiments, at least one radiating disk is coupled to respective ones of the at least one radiating rod. The radiating rod can be coupled to an interface of the first and second porous sections. The first or second porous sections can be formed of ceramic material and/or metallic materials. In some embodiments, the first or second porous medium comprises metallic fibers, screens, or foam. The one or more radiating rods can include fins. The preheater inlet can be coupled to a source of colder air, which is heated by being placed proximate the radiating rod to provide heated air to the fuel inlet as part of a fuel air mixture for the burner. In another embodiment, the flame holder generates a flame at an interface of the first and second porous sections.
In another embodiment, a method of preheating gaseous fluids in superadiabatic burners is provided. The can include delivering a primary fuel mixture to a flame holder formed from a porous medium, the flame holder comprising a fuel inlet and a fuel outlet; establishing a flame inside the flame holder with the primary fuel mixture and heating one or more radiating rod coupled to the porous medium; delivering a gaseous fluid to an inlet of a preheater and passing the gaseous fluid through one or more passageways of the preheater to an outlet of the preheater, the outlet being coupled to the fuel inlet, the one or more passageways being in heat transfer contact with the heated one or more radiating rods to raise the temperature of the gaseous fluid as it passes through the one or more passageways; and mixing the raised temperature gaseous fluid with the primary fuel mixture and delivering the mixture of raised temperature gaseous fluid and primary fuel mixture to the porous medium. The mixture of raised temperature gaseous fluid and primary fuel mixture can be ignited to generate a local superadiabatic temperature inside the porous medium.
In some embodiments, the gaseous fluid is air or a mixture of air and propane. The primary fuel mixture is a first mixture of air and propane and the gaseous fluid is a second mixture of air and propane. In other embodiments, the gaseous fluid and/or primary fuel mixture can comprise other combustible fluids. The porous medium can include a first porous section and a second porous section and the act of establishing a flame inside the flame holder can include establishing a flame at an interface of the first and second porous sections. Radiating disks can be coupled to the one or more radiating rods and a radiant surface can be provided at the one or more radiating disks that is at or near the superadiabatic temperature. Radiation heat can be delivered from the radiant surface to a target surface.
In some embodiments, the one or more radiating rods can include fins and the heat transfer contact can be between respective fins of the one or more radiating rods and the gaseous fluid as the gaseous fluid passes through the one or more passageways. The heating of the gaseous fluid can expand the fuel lean limit and increase the inlet temperature of the mixture of raised temperature gaseous fluid and primary fuel mixture. In other embodiments, the temperature of the radiant surface exceeds a temperature of gas exiting the flame holder. In some embodiments, the temperature of the radiant surface does not exceed 1600 K.
In this regard, it is to be understood that the claims provide a brief summary of varying aspects of the subject matter described herein. The various features described in the claims and below for various embodiments may be used in combination or separately. Any particular embodiment need not provide all features noted above, nor solve all problems or address all issues in the prior art noted above.
The patent of application file contains at least one drawing executed in color. Copies of this patent or patent application publication with color drawing(s) will be provided by the Office upon request and payment of the necessary fee.
Unless otherwise explained, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this disclosure belongs. In case of conflict, the present specification, including explanations of terms, will control. The singular terms “a,” “an,” and “the” include plural referents unless context clearly indicates otherwise. Similarly, the word “or” is intended to include “and” unless the context clearly indicates otherwise. The term “comprising” means “including;” hence, “comprising A or B” means including A or B, as well as A and B together. Although methods and materials similar or equivalent to those described herein can be used in the practice or testing of the present disclosure, suitable methods and materials are described herein. The disclosed materials, methods, and examples are illustrative only and not intended to be limiting.
Radiant porous burners, such as propane radiant porous burner, are used, for example, for drying and other farm-related processes. Their efficiency is typically under 25 percent and decreases with radiating surface temperature (which is characterized by thermal radiation emissive wavelength). The present disclosure provides a radiant burner, such as a porous burner, that uses air preheating to create a superadiabatic region in the burner. Radiation corridors begin in the superadiabatic region and effectively transport radiation to the surface. In some implementations, burner efficiency is about 43 percent. In further implementations, burner efficiency is greater than about 25 percent or between about 25 percent and about 43 percent. In some implementations, the radiant burner is constructed from a metallic substance. In further implementations, the burner has optimized heat exchanger/transport components.
Through internal heat recirculation (as in flame held inside a porous medium), it is possible to raise the reacting gas temperature locally to above the adiabatic temperature (superadiabatic) before it eventually returns to the adiabatic temperature further downstream. Commercial radiant burners typically use lower surface temperature than the adiabatic temperature for radiative heating and these are inherently not highly efficient (less than 20 percent). It does not appear that any attempt has been made to design a radiant burner to create the downstream radiation temperature higher than the adiabatic temperature using a preheater (external heat recirculation). The present disclosure provides a radiant burner, such as a propane radiant burner, operating at fuel lean conditions with superadiabatic radiation (Superadiabatic Radiant Burner, SRB). The burner is shown in
The primary fuel-rich (the stoichiometry after mixing with preheated air is less than 0.4 stoichiometry) propane-air mixture enters a porous medium (PM) as the flame holder. This PM is generally a ceramic foam, but because of the lower flame temperature due to the fuel lean combustion, metallic structures (such as screens or fibers) may be used in some examples. Metallic structures may allow for more flexible or less expensive burner design.
Once the flame is established inside this PM, the combustion flue heat is recirculated through the preheater (PH), which will contain the secondary flow (in some cases, air only). The fuel-lean propane-air mixture of primary fuel-rich and secondary preheated air flows would then be ignited creating a local superadiabatic temperature inside the porous medium. From this superadiabatic region, heat conducting solids (like rod-disk elements) extend and then make up the radiant surface. This is referred to as the radiation rod (RR or radiation corridor).
The radiant surface at near superadiabatic temperature will deliver radiation heat to a target surface at higher efficiency than typical conventional designs. This heat recirculation is shown in
The SRB design may increase the radiation surface temperature possible for stable operation. In a particular configuration, the system temperatures are minimized as appropriate to allow for the use of metallic parts (such as PM, PH, and RR). Since the heat exiting will be in part by convection (given by the exit gas temperature) and in part by radiation, it can be beneficial to minimize the temperature of the exiting gas while maintaining the radiation surface temperature close to a superadiabatic temperature.
The design of an example SRB system is shown in
The comparison of the thermal efficiency at different flame speeds and fuel ratios is shown in
One reason for this improvement may be attributed to the higher radiation surface temperature than the gas exit temperature shown in
It is also shown in
In a specific design of the disclosed burning, the burner is made of all metallic porous media and radiation corridor and preheater. In a more specific design, the media is carbon or stainless steel or copper. The porous media is fabricated from, for example, pressed fine screens in PM1 and coarse ones in PM2. The fins of the radiation rod are either press joined/welded or machined. The fins of the preheater will follow the same. Other burners according to the present disclosure may be constructed differently or from different materials.
Additional details regarding the construction and operation of the disclosed burner are shown in
As discussed above, the novel structures disclosed herein provide effective preheating and radiation routing to increase efficiency of the burner. Flue gas heat can be recovered to increase the inlet air temperature and raises the flame temperature locally above the adiabatic temperature (superadiabatic flame) for the fuel-lean conditions. The heat from the superadiabatic region is then extracted and conducted through embedded, high-thermal conductivity radiation corridors and is radiated, at a higher temperature than the flue gas, to the target. The analyses of local thermal non-equilibrium among the gas phase, two-layer porous solid, preheating heat exchanger, and radiant corridor are presented for the zeroth-order reaction of premixed methane/air. Radiant burner efficiency over 45% is predicted.
The heat transfers and mass flow in the superadiabatic radiant burner system are shown in
Porous Burner
The porous burner consisting of upstream (PM 1) and downstream (PM2) porous media as shown in
The continuity, species and energy equations are discretized using finite volume method over the computational domain of the porous media (PM1 and PM2).
The density of the gas flow is computed from the ideal gas law, in which the properties of the gas mixture are considered and is given by
The interstitial convective heat transfer is modeled by the volumetric Nusselt number and is given by
NU
D,p
=CRe
m, (6)
where C and m values are listed in Table 1. Re is the Reynolds number of the gas flow in the porous media and is given by
Re=ερ
g
u
g
D
p/μ (7)
The specific volume of the porous media is given by
A
gs
/V=ε/D
p. (8)
The effective thermal conductivity of the gas phase consists of diffusion and dispersion terms and is given by
k
g,e
=εk
g+(ρcp)gDxxd, (9)
where the thermal diffusivity is given by
D
xx
d=0.5αgPe, (10)
and the Peclet number is given by
Pe=ρ
g
c
p
εu
g
D
p
/k
g. (11)
The Lewis number is assumed to be unity as below,
where the mass diffusivity is given by
D
g,e
=εD
g
+D
m
d. (13)
The effective thermal conductivity of the solid phase consists of the volume-averaged thermal conductivity and the radiative thermal conductivity of the solid phase and is given by
k
s,e=(1−ε)ks+εks,r, (14)
where the radiative thermal conductivity is given by
The zeroth-order reaction rate is used to model the combustion of fuel/air mixture and is given by
{dot over (n)}
g,r,F
=−a
r
e
−ΔE
/R
T
, (16)
where the coefficients of the combustion model (ar and DEa) for premixed methane/air flow are listed in Table 1.
Since the specific heat capacity and thermal conductivity of the gas phase significantly vary with temperature, they are given as the functions of temperature by fourth-order polynomial equations listed in Table 2.
The perfect mixing of the preheated air and fuel is assumed at the inlet of the burner. The equivalence ratio of the fuel/air mixture is defined as φ=(ρF,g/ρg)/(ρF,g/ρg)stoich. The velocity of the fuel/air mixture (ug), entering the burner, is calculated by the mass conservation equation which is given by
ρgugHW[1−φ(ρF,g/ρg)stoich]=NtuρairuairπRru2 (17)
The boundary conditions for the energy and species equations are presented below.
Inlet (x=0):
Outlet (x=LPM):
It is assumed that the porous burner exchanges radiation heat at the outlet with the preheater at its average temperature. All the properties used for the numerical analysis are evaluated based on the mass-averaged mixture of air and fuel.
The governing equations of the porous burner are discretized using uniform grid nodes. The equations are solved by enough iteration until a convergence is achieved. The continuity equation of the gas flow, Eq. (1) is directly used to calculate the velocity at each node. The density of the gas flow is computed by ideal gas law. The initial temperature profiles for gas and solid phases with their peak temperatures at the interface of the upstream and downstream porous media are set to ignite the flame. Note that all properties are smoothed near the interface of two porous media to avoid numerical errors due to discontinuous properties. But the porosity of the porous media was allowed to vary across the interface (Eq. (4)).
Radiation Rods and Preheater
An exemplary radiation rods and preheater system are shown in
The radial fins of the radiation rods are modeled by considering the convection and conduction heat transfers. The equations and boundary conditions are given by
where wf is the half thickness of each fin.
The convection heat transfer is considered for the radial fins with an insulated tip boundary condition. The stem of the radiation rod is divided to as many nodes as aligned with the preheater tubes as shown in
The energy equations of the stem of the finned section of the radiation rods shown in
where m={NuD,pkg/[(Ags/V)Dp2kRRwf]}1/2 and perfect insulation is assumed as the boundary condition for the first node (i=1), i.e., Toj=T1j
It is assumed that the presence of the radiation rods embedded in the downstream porous medium (PM2) do not affect the combustion occurring in the upstream porous medium (PM1). However, the specific volume of the downstream porous medium (PM2), Ags/V is corrected considering the presence of the radiation rods and fins. Note that the burner is modeled as a one-dimensional system while the radiation rods and fins are modeled as two-dimensional systems.
The energy balance of the gas flow in the finned section of the radiation rods is given by
{dot over (m)}
h
c
p,h[(T∞)i,j−(T∞)i+1,j]+4πRRRwfCfkRR[Ti,j−(T∞)i,j]=0,
i=1, . . . , Nf. (29)
The unfinned section of the radiation rod is assumed to be insulated to reduce the heat loss to the surrounding gas flow and its energy equations are given by
where the heat transfer coefficient is defined by the correlation of an appropriate compact heat exchanger and is given by
and Tt is the temperature of a target (heat sink).
The convective heat transfers between the flue gas, the radiation rod and the preheater are calculated in two steps. First the convective heat transfer to the radiation rod is calculated using the flue gas temperature, T∞ by Eq. (27) and Eqs. (30)-(32). Then the reduced flue gas temperature, T∞,pH is used to calculated the energy conservation equations of the flue gas flow which is given by
{dot over (m)}
h
c
p,h[(T∞)N
i=1, . . . , Ntu. (35)
The heat transfer in the preheater tubes is modeled by ε-NTU method in which each tube is considered separately and the tube length is also divided into small nodes to be aligned with the radiation rods as shown in
where NTU is calculated by
where U is the overall heat transfer coefficient of the preheater including the internal and external convective heat transfer coefficients. Each node of the preheater tube is solved to find the outlet air temperature of the node. The outlet air temperature is used as the inlet air temperature for the next adjacent node of the preheater tube. The air temperature in the preheater is calculated at the boundary of two adjacent nodes and is given by
C
c[(TPH)i,j−(TPH)i+1,j]=εCmin[(T∞,PH)i,j−(T∞,PH)i,j−1], j=1, . . . , NRR. (38)
The temperature of the flue gas flow from each node, which is used as the ambient temperature for the radiation rods, is given by
C
h[(T∞,PH)i,j−(T∞)i+1,j]=εCmin[(T∞,PH)i,j−(TPH)i,j−1], j=1, . . . , NRR. (39)
The algebraic equations governing the radiation rods and preheater are solved using the IMSL library.
The thermal efficiency of the burner is defined as the ratio of the radiation output to the target and the combustion heat and is defined by
where the radiation output is given by
Q
rs=Σ(εrArsσSBTrs4−εrAtσSBTt4) (41)
and the combustion heat is given by
The convective heat transfer (QRR in
Heat Recirculation of Superadiabatic Radiant Burner
It was found from the results of the numerical analysis that the flame speeds are in good agreement with the experimental results in Table 3. The superadiabatic radiant burner with two-layer porous burner (PM1 and PM2), a preheater (PH) and radiation rods (RR) was analyzed. The temperature profiles of the superadiabatic radiant burner are depicted in
As a result of the preheating and separate heat transfer through the radiation rods, the temperature of the radiating surface is greater than the flue gas temperature and close to the adiabatic temperature. It is shown in
The temperature and gas species profiles in the upstream porous medium (PM1) near the flame location are magnified in
The heat fluxes for the solid phase are shown in
where the integral limits (e and w) denote the right (east) and left (west) faces of each node, respectively which are commonly used in the finite volume method. It is shown in
The heat fluxes for the gas phase near the flame are shown in
It is shown in
Preheating of Superadiabatic Radiant Burner
The superadiabatic radiant burner combines the heat recovery by a preheater from the exit flue gas with the internal heat circulation in the porous burner. The external heat recovery (preheating) raises the inlet gas temperature and further expands the fuel lean flammability limit beyond that of the conventional porous burner.
The overall energy balance of the superadiabatic burner is given by
Q
cb
=Q
rs
+Q
r,in
+Q
g (51)
where Qcb is the combustion heat, Qrs is the radiation output to the heating target, Qr,in is the radiation loss to the surrounding at the inlet and Qg is the enthalpy loss by the flue gas and is given by
Q
g
=Q
g,o−(Qg,in+QF,in) (52)
where Qg,o is the energy carried by the flue gas, Qg,in is the energy carried by the air into the preheater, and QF,in is the energy carried by the fuel to the burner as shown in
1=Q*rs+Q*r,i+Q*g. (53)
Note that the normalized radiation output (Q*rs) is equal to the thermal efficiency (η) of the superadiabatic radiant burner. The normalized energy balance for the baseline condition (preheater air velocity uair=0.06 m/s) is shown in
The flame location in the upstream porous medium (PM1) for different preheating air velocities and equivalence ratios is depicted in
The thermal efficiencies of the superadiabatic radiant burner at various equivalence ratios and preheater air velocities are shown in
A novel superadiabatic radiant porous burner using a preheater and radiation rods was presented and was numerically analyzed. The numerical results showed that thermal efficiency over 45% can be achieved. In the radiant burner, a preheater was used to externally recover the heat from the flue gas and increase the inlet air temperature so that the burner could operate at more fuel lean conditions than the conventional burners. The radiation rods, made of a metallic material (carbon steel) of high thermal conductivity, were used to transfer the combustion heat directly to the radiating surface at higher temperature than that of the flue gas. It was shown that combining the internal heat recirculation found in the conventional porous burners with the external heat recovery of the preheater and efficient heat transfer through the radiation corridors, allows the superadiabatic radiant burner to achieve higher radiating surface than the flue gas temperature and near the adiabatic flame temperature. As a result, a significant improvement in the thermal efficiency for the superadiabatic radiant burner is achieved as compared to the conventional porous burner.
It is to be understood that the above discussion provides a detailed description of various embodiments. The above descriptions will enable those skilled in the art to make many departures from the particular examples described above to provide apparatuses constructed in accordance with the present disclosure. The embodiments are illustrative, and not intended to limit the scope of the present disclosure. The scope of the present disclosure is rather to be determined by the scope of the claims as issued and equivalents thereto.
This application claims the benefit of U.S. Provisional Application No. 61/658,820, which was filed on Jun. 12, 2012 and is incorporated herein by reference in its entirety.
Number | Date | Country | |
---|---|---|---|
61658820 | Jun 2012 | US |