Flow divider for radiant wall burner

Information

  • Patent Grant
  • 6379146
  • Patent Number
    6,379,146
  • Date Filed
    Monday, April 9, 2001
    23 years ago
  • Date Issued
    Tuesday, April 30, 2002
    22 years ago
Abstract
A flow divider for use in a gas burner assembly supported in an opening in a furnace wall has injected fluid, such as gas and/or air, flowing through an inner burner pipe then outwardly through a plurality of openings for burning along the surface of a wall thus providing a near uniform radiant heat energy to the furnace. The flow divider has a plurality of nested members and a plurality of in-line members to divide the flowing gas and/or air to improve distribution and to promote more uniform mixing of the gas and air.
Description




FIELD OF THE INVENTION




This invention relates generally to an apparatus for a radiant wall burner assembly. More particularly, but in no way limiting, the present invention relates to a flow divider apparatus contained in a gas burner apparatus having a burner pipe.




BACKGROUND OF THE INVENTION




Radiant wall burners have been previously disclosed in the prior art. These prior art burners typically include the use of a burner pipe which is usually inserted into an oversized opening through the wall of a furnace terminating at a downstream end perpendicular to and beyond the inner wall of the furnace. The inner wall of the furnace surrounding the furnace opening typically includes a radiant wall surface which is substantially perpendicular to the burner pipe. The downstream end of the burner pipe is typically closed by a cap, plug, or other device. A plurality of openings, such as slots or holes, are provided in the side wall of the burner pipe at the downstream end to project a fluid mixture, such as a gas/air mixture, outwardly along the radiant furnace wall surface for burning.




Fuel is introduced into the burner pipe around its centerline, while air is introduced at or near the pipe's wall. While some mixing of the air and fuel occurs, due to the velocity of the gas/air mixture flow, the center portion of the flow stream remains fuel rich while the portion flowing near the furnace wall is fuel lean. When such a mixture combusts, the majority of the heat produced occurs away from the furnace wall, reducing effectiveness and efficiency of the furnace.




In order to assist the fluid flow from the burner pipe outward across the radiant wall, some prior art burners have utilized a flow divider which is inserted into the burner pipe.

FIGS. 1-3

generally depict a typical prior art flow divider within a burner pipe. Unfortunately, however, the prior art flow dividers have not been able to adequately mix the fluid, especially around the centerline, into a uniform mixture prior to discharging into the furnace. These flow dividers continue to provide a fluid mixture which has a fuel rich center or downstream portion while having a fuel lean annular or upstream portion, as illustrated in FIG.


3


.




U.S. Pat. No. 2,671,507, issued to Morck, which is incorporated herein by reference, discloses a radiant gas burner having a distributor for dividing the flow stream into a plurality of gas streams. The distributor utilizes a centralized plug and a plurality of fins to provide passages for the gas streams.




U.S. Pat. No. 4,702,691, issued to Ogden, which is incorporated herein by reference, discloses a radiant gas burner having a single cylindrical flow divider for dividing the flow stream into an upstream portion and a downstream portion. The flow divider creates a substantially undivided annular space between the burner pipe wall and the flow divider through which the upstream portion flows and an undivided inside central space within the flow divider through which the downstream portion flows. This device unfortunately does not provide for sufficient mixing of the fluid stream. Thus, the fluid stream remains primarily fuel rich along its downstream, or center, portion.




This invention is an improvement upon the radiant wall burning apparatuses heretofore developed. Specifically, the invention is directed to an improved flow divider for use in radiant wall burners.




SUMMARY OF THE INVENTION




The present invention provides a flow divider apparatus for a gas burner assembly which satisfies the needs and alleviate the problems discussed above. The inventive flow divider apparatus provides uniform flow velocities and also provides improved distribution of air or gas-air mixtures through the openings or slots provided in the end portion of the burner pipe.




A typical gas burner assembly in which the inventive flow divider apparatus is utilized can be employed, for example, in furnaces in which a high velocity fuel gas enters a burner pipe via an orifice to mix with combustion supporting air in a mixing section of the burner pipe. The burner pipe will typically be inserted into an oversized opening through the wall of the furnace such that the burner pipe is substantially perpendicular to, and the downstream end thereof extends beyond, the inner wall of the furnace. The inner wall of the furnace surrounding the furnace opening typically includes a radiant wall surface which is substantially perpendicular to the burner pipe. The downstream end of the burner pipe is typically closed by a cap, plug, or other device. A plurality of lateral side wall openings, such as slots or holes, are provided in the downstream end portion of the burner pipe to discharge the gas-air mixture outwardly along the radiant furnace wall surface for burning. Generally, the flow divider of the present invention is placed within the burner pipe near the downstream end thereof in order to divide the flow stream into a plurality of separate flow streams, each preferably being discharged at a different longitudinal location in the side wall of the burner pipe proximate to its distal end.




The present invention allows the fluid stream to mix more thoroughly due to turbulence caused by the impact of the fluid stream with the divided center section. This more thorough mixing of the fuel and air contained in the fluid stream allows for a more uniform and efficient distribution of fuel/air gases than previously provided by the prior art devices. As a result of the more uniform distribution of the fuel and air mixture, combustion is more balanced and a more even heat flux is provided.




In one aspect, the present invention involves a gas burner assembly for use in a furnace in which fluid flows therethrough. The assembly comprises: (a) a burner pipe through which fluids flow and (b) a flow divider comprising a plurality of nested members within said burner pipe defining an annular flow space between the side wall of the burner pipe and the outermost member, a core space within the innermost member, and at least one midstream space between the nested members. The burner pipe includes a plurality of openings or slots provided in the side wall of the burner pipe proximate to its distal (downstream) end.




As used herein, the term nested refers to the interfitting of two or more members. For example, when the number of nested members is two, there would be an outer member and an inner member. When the number of nested members is three, there would be an outer member, an inner member, and a midstream member located between the outer member and inner member.




The inventive flow divider is preferably positioned inside the burner pipe at the downstream end. The fluid stream is divided into a downstream portion which passes through the core space, an upstream portion which passes through the annular space, and at least one mid-stream portion which passes through at least one midstream space. The fluid stream then passes out the plurality of openings located in the burner pipe. The fluid which flows therethough can be, but is not limited to, a combination of pre-mixed fuel and aspirated combustion supporting air.




By way of example, when the flow divider of the present invention has two nested members, an annular flow space is formed between the side wall of the burner pipe and the outer member, a core space is formed within the inner member, and a midstream space is formed between the outer member and the inner member. When the number of nested members is three, an annular flow space is formed between the side wall of the burner pipe and the outermost member, a core space is formed within the innermost member, a first midstream space is formed between the outermost member and the middle member, and a second midstream space is formed between the middle member and the innermost member.




In another aspect of the inventive flow divider, the cross-section of each of the nested members is substantially cylindrical. It will, however, be understood by those skilled in the art that other geometric cross-sections could be utilized.




In another aspect of the inventive flow divider, each of the openings or slots around the downstream end portion of the burner pipe is divided into a downstream portion, an annular portion, and at least one midstream portion by flaring the downstream ends of the plurality of nested members such that they intersect and divide the openings in the side wall of the burner pipe. This flaring can be configured in a curved, tapered or beveled manner. Alternatively, a squared radial (i.e. substantially 90°) flaring perpendicular to the burner pipe openings can be used.




In yet another aspect, the flow divider of the present invention comprises a plurality of in-line members defining a plurality of flow sections. These plurality of in-line members preferably intersect along a longitudinally extending centerline or edge and generally extend radially from the centerline or edge toward the side wall of the burner pipe. The plurality of flow sections are defined by the spaces created between adjacent in-line members.




By way of example, when the number of in-line members is three, each extending from a common edge or centerline located substantially along the centerline of the burner pipe, a first flow section is created between the first in-line member, the second in-line member and the side wall, a second flow section is created between the second in-line member, the third in-line member and the side wall, and a third flow section is created between the third in-line member, the first in-line member and the side wall.




In yet another aspect, the present invention involves a gas burner assembly for use in a furnace in which fluid flows therethrough. The assembly comprises: (a) a burner pipe through which fluids flow and (b) a flow divider comprising a plurality of nested members within said burner pipe defining an annular flow space between the inside diameter of the burner pipe and the outermost nested member, a core space within the innermost nested member, and at least one midstream space between the nested members, and (c) a plurality of in-line members defining a plurality of flow sections, further dividing the annular space, the core space, and/or the midstream space(s), either individually or in combination. The burner pipe includes a plurality of openings or slots provided in the side wall of the burner pipe proximate to its distal (downstream) end.




By way of example, when the flow divider of this aspect of the present invention has two nested members and three in-line members, an annular flow space is formed between the side wall of the burner pipe and the outer member, a core space is formed within the inner member, and a midstream space is formed between the outer member and the inner member. The in-line members further divide the annular space, core space and/or midstream space into flow sections.




It is understood that the in-line members can divide the annular space, core space and midstream space either individually or in combination. By way of example, the in-line members may only be placed within the core space, thus dividing only the core space while not affecting the remaining flow spaces. By further example, the in-line members may only be placed within the core space and at least one midstream space, further dividing those spaces while not affecting the remaining spaces.




A better understanding of the present invention, its several aspects, and its advantages will become apparent to those skilled in the art from the following detailed description, taken in conjunction with the attached drawings, wherein there is shown and described the preferred embodiments of the invention, simply by way of illustration of the best mode contemplated for carrying out the invention.











BRIEF DESCRIPTION OF THE DRAWINGS





FIGS. 1-3

demonstrate prior art flow dividers.





FIG. 4

is a perspective view of a radiant wall burner incorporating an embodiment


10


of the flow divider of the present invention.





FIG. 5

is a cross-sectional view of embodiment


10


show in

FIG. 4

along line AA.





FIG. 6

is a perspective view of the radiant wall burner incorporating an embodiment


60


of the flow divider of the present invention showing the side wall slots located therein.





FIGS. 7-8

illustrate alternative embodiments of the flow divider of the present invention.





FIG. 9

is a bottom view of embodiment


80


of the flow divider of the present invention.





FIG. 10

is bottom view of embodiment


100


of the flow divider of the present invention





FIG. 11

is a cross-sectional view of

FIG. 10

along line BB.











DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS




Before explaining the present invention in detail, it is to be understood that the invention is not limited in its application to the details of the construction and arrangement of parts illustrated in the accompanying drawings. The invention is capable of other embodiments and of being practiced or carried out in a variety of ways. It is to be understood that the phraseology and terminology employed herein is for the purpose of description and not of limitation.




An embodiment


10


of the present invention is generally illustrated in

FIGS. 4 and 5

. Embodiment


10


comprises a burner pipe


11


, which is inserted through an opening


42


located through a furnace wall


40


, having a flow divider


20


preferably provided in the interior of burner pipe


11


adjacent the downstream end. Flow divider


20


preferably comprises a plurality of nested members within burner pipe


11


. Although shown as a gas-air mixing burner assembly, it will be understood by those skilled in the art that the inventive gas burner assembly could be could be used with other burner assemblies.




As used herein, the term nested refers to the interfitting of two or more members. For example, when the number of nested members is two, there would be an outer member and an inner member. When the number of nested members is three, there would be an outer member, an inner member, and a midstream member located between the outer member and inner member.




As stated, this invention is directed to improvements in the flow of the fluids, such as gas-air mixtures, from the downstream end of the burner pipe


11


. A plug


12


is preferably positioned to close the downstream end of pipe


11


. Plug


12


is conical but other types of plugs, caps or similar devices could also be used. A plurality of spaced, lateral openings or slots


21


are provided around the circumference of the side wall of the downstream end of the burner pipe


11


. The gas and air mixture is discharged radially outward through openings


21


for burning along the inner furnace wall and tile surface


46


.




As shown in

FIGS. 4 and 5

, flow divider


20


is shown as having a plurality of nested cylindrical members comprising a first cylindrical member


16


and a second cylindrical member


18


. The nested cylindrical members create a plurality of separate spaces through which the flow stream travels. An annular space


50


is created between the interior wall of burner pipe


11


and first cylindrical member


16


. A midstream space


52


is created between first cylindrical member


16


and second cylindrical member


18


. A core space


54


is created within second cylindrical member


18


.




It will be understood by those skilled in the art that, while the nested members of this embodiment have a cylindrical cross-section, other geometric cross-sections could be utilized.




In one aspect, the various surfaces of flow divider


20


provide a substantial amount of surface area over which the fluid must travel. This increased contact operates to significantly increase the amount, and enhances the uniformity of, mixing occurring in the inventive apparatus.




It is noted one or generally any other number of nested members can be in the present invention. Further, as will be understood by those skilled in the art, the inventive flow divider


20


can be either removably installed or permanently installed in burner pipe


11


.




In another embodiment


60


, as shown in

FIG. 6

, the downstream ends


72


of the nested members employed in flow divider


70


are preferably flared (i.e., curved, shaped, flanged or otherwise directed outwardly) so as to intersect the lateral sidewall openings


62


provided around the downstream end portion of burner pipe


61


, thus dividing each of the openings


62


into a plurality of opening sections. By way of example, flow divider


70


is shown as having two nested members


76


and


78


each of which includes a curved flared downstream end


72


and


73


. These curved flared downstream ends


72


and


73


intersect openings


62


and thereby divide each of openings


62


into a downstream opening section


64


, an upstream opening section


66


and a midstream opening section


68


, as shown in FIG.


6


. It will be understood by those skilled in the art that the number of opening sections created will increase as the number of nested members increases.




In the embodiment depicted in

FIGS. 7 and 8

, the flared downstream ends of the nested member can comprise, for example, a tapered surface


74


and/or a perpendicular surface


73


.




As illustrated in

FIG. 9

, another embodiment


80


of the present invention comprises a burner pipe


81


having a flow divider


90


preferably provided in the interior of burner pipe


81


adjacent the downstream end. Flow divider


90


preferably comprises a plurality of in-line members


94


which divide the flow stream into flow sections. These plurality of in-line members generally comprise a plurality of plates having a common central, longitudinal edge and extending radially toward the side wall of the burner pipe. The plurality of flow sections are defined by the spaces created between adjacent in-line members and the inner wall of the burner pipe.




As illustrated in

FIGS. 10 and 11

, another embodiment


100


of the present invention comprises a burner pipe


102


having a flow divider


110


preferably provided in the interior of burner pipe


102


adjacent the downstream end. Flow divider


110


preferably comprises a plurality of nested members


120


within burner pipe


102


and a plurality of in-line members


130


. The combination of nested members


120


and in-line members


130


divides the space within the interior of burner pipe


102


.




In one aspect of this embodiment, flow divider


120


utilizes three in-line members


132


,


134


, and


136


along with two nested members


122


and


124


defining a core space


140


, an annular space


142


and a midstream space


144


. Each in-line member


132


,


134


, and


136


is a substantially L-shaped plate having a body portion


138


and a leg portion


139


. Body portion


138


is positioned within core space


140


along its length and preferably extends to plug


104


. Leg portion


139


extends radially outward toward the interior wall of burner pipe


102


and contacts the upstream ends of the nested members


122


and


124


, as illustrated in FIG.


11


. In this aspect, each in-line member


132


,


134


, and


136


in combination with the nested members


122


and


124


create three distinct flow regions for core space


140


, as illustrated by numerals C


1


-C


3


.




It will be understood by those skilled in the art that in-line members


130


can alternatively extend into and divide the annular space


142


, core space


140


and/or any or all of the midstream spaces


144


, either individually or in combination.




While the invention has been described with a certain degree of particularity, it is manifest that many changes may be made in the details of construction and the arrangement of components without departing from the spirit and scope of this disclosure. It is understood that the invention is not limited to the embodiments set forth herein for purposes of exemplification, but is to be limited only by the scope of the attached claim or claims, including the full range of equivalency to which each element thereof is entitled.



Claims
  • 1. A burner apparatus for furnaces comprising:a burner pipe having a side wall, a distal end portion, and a plurality of lateral openings in said side wall around said distal end portion; a flow divider comprising at least three in-line members within said burner pipe forming at least three longitudinal flow sections; a gas fuel intake in said burner pipe upstream of said flow divider; and an air intake in said burner pipe upstream of said flow divider such that gas fuel from said gas fuel intake and air from said air intake will form a fuel and air fluid stream which will flow through said longitudinal flow sections of said flow divider and out of said lateral openings.
  • 2. The burner apparatus of claim 1 wherein each of said in-line members extends from a common edge radially outward toward said side wall of said burner pipe.
  • 3. The burner apparatus of claim 2 wherein each of said in-line members contacts said side wall of said burner pipe.
  • 4. A burner apparatus for furnaces comprising:a burner pipe having a side wall, a distal end portion, and a plurality of lateral openings through said side wall in said distal end portion; a flow divider comprising a plurality of nested members within said burner pipe; a gas fuel intake in said burner pipe upstream of said flow divider; and an air intake in said burner pipe upstream of said flow divider such that gas fuel from said gas fuel intake and air from such air intake will form a fuel and air fluid stream which will flow through said flow divider and out of said lateral openings, wherein said plurality of nested members include at least an inner member and an outer member such that said inner member is positioned within said outer member, a longitudinal core flow passage for said fuel and air fluid stream is provided through said inner member, a longitudinal annular flow space for said fuel and air fluid stream is provided between said outer member and said side wall, and at least one longitudinal intermediate flow space for said fuel and air fluid stream is provided between said inner member and said outer member.
  • 5. The burner apparatus of claim 4 wherein said plurality of nested members are substantially coaxial.
  • 6. The burner apparatus of claim 4 wherein said plurality of nested members are partially cylindrical nested members.
  • 7. The burner apparatus of claim 4 wherein the number of said plurality of nested members is three such that two intermediate longitudinal flow spaces for said fuel and air fluid stream are provided between said inner member and said outer member.
  • 8. The burner apparatus of claim 4 wherein each of said plurality of nested members has a flared downstream end intersecting said lateral openings.
  • 9. The burner apparatus of claim 8 wherein said flared downstream end of each of said plurality of nested members is a curved end portion.
  • 10. The burner apparatus of claim 8 wherein said flared downstream end of each of said plurality of nested members is substantially perpendicular to said lateral openings.
  • 11. The burner apparatus of claim 8 wherein said flared downstream ends of said plurality of nested members divide each of said openings into a plurality of opening sections.
  • 12. The burner apparatus of claim 11 wherein:said flared downstream ends of said plurality of nested members divide each of said lateral openings into a downstream opening section, an upstream opening section, and at least one intermediate opening section, and wherein a first portion of said fuel and air fluid stream will flow through said core flow passage then outwardly through said downstream opening sections, a second portion of said fuel and air fluid stream will flow through said annular flow space thence outwardly through said upstream opening sections, and a third portion of said fuel and air fluid stream will flow through said intermediate flow space thence outwardly through said intermediate opening sections.
  • 13. A burner apparatus for furnaces comprising:a burner pipe having a side wall, a distal end portion, and a plurality of lateral openings through said side wall in said distal end portion; a flow divider within said burner pipe; a gas fuel intake in said burner pipe upstream of said flow divider; and an air intake in said burner pipe upstream of said flow divider such that gas fuel from said gas fuel intake and air from said air intake will form a fuel and air fluid stream which will flow through said flow divider and out of said late openings, wherein said flow divider comprises a plurality of nested members including at least an outer member positioned within said side wall of said burner pipe and an innermost member positioned within said outer member such that a longitudinal core flow passage for said fuel and air fluid stream is provided though said innermost member, a longitudinal annular flow space for said fuel and air fluid stream is provided between said outer member and said side wall, and at least one longitudinal intermediate flow space for said fuel and air fluid stream is provided between said innermost member and said outer member, and a plurality of in-line members which divide at least said core flow passage into at least three parts.
  • 14. The burner apparatus of claim 13 wherein said plurality of nested members are substantially coaxial.
  • 15. The burner apparatus of claim 13 wherein said plurality of nested members are partially cylindrical nested members.
  • 16. The burner apparatus of claim 13 wherein said plurality of in-line members extend from a common edge radially outward toward said side wall of said burner pipe.
  • 17. The burner apparatus of claim 16 wherein each of said plurality of in-line members contacts said side wall of said burner pipe.
  • 18. The burner apparatus of claim 13 wherein each of said in-line members comprises:a body portion positioned along the length of said plurality of nested members; and a leg portion extending radially outward toward said side wall of said burner pipe.
  • 19. The burner apparatus of claim 18 wherein each of said nested members has an upstream end and a downstream end, and said leg portion of each of said in-line members contacts said upstream end of each of said nested members.
  • 20. The burner apparatus of claim 13 wherein each of said plurality of nested members has a flared downstream end portion which intersects said lateral openings.
  • 21. The burner apparatus of claim 20 wherein said flared downstream end portions of each of said plurality of nested members are curved.
  • 22. The burner apparatus of claim 20 wherein said flared downstream end portions of said plurality of nested members are substantially perpendicular to said lateral openings.
  • 23. The burner apparatus of claim 20 wherein said flared downstream end portions of said plurality of nested members divide each of said lateral openings into a plurality of opening sections.
  • 24. The burner apparatus of claim 23 wherein:said flared downstream end portions of said plurality of nested members divide each of said openings into a downstream opening section, an upstream opening section, and at least one intermediate opening section, and wherein a first portion of said fuel and air fluid stream will flow through said core flow passage then outwardly through said downstream opening sections, a second portion of said fuel and air fluid stream will flow through said annular flow space thence outwardly through said upstream opening sections, and a third portion of said fuel and air fluid stream will flow through said intermediate flow space thence outwardly through said intermediate opening section.
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