This invention relates to fuel burner equipment and more particularly to a premixed fuel burner assembly.
Premixed fuel burner assemblies are used with various heating equipment such as boilers, commercial hot water headers, fuel barbeques, and the like. Fuel burners are devices into which a flow of combustible fuel (usually gas) is introduced into a mixing chamber, where it is mixed with air supplied in a suitable proportion to the combustible gas. After mixing, the mixture of combustible fuel and air exits the mixing chamber through burner ports where it is ignited and burnt.
Specifically, a typical premixed fuel burner assembly consists of a hollow burner body having a closed end and an open end into which the premixed fuel/air flows. The burner body includes a porting area that consists of burner flame port perforations (i.e. slots and/or holes). Within the burner body is a venturi tube that typically contains a multiplicity of holes through and out which the fuel and air mixture from the interior of the body flows. Fuel and air are both provided into the boiler body through the venturi tube. Specifically, fuel is provided into the venturi tube through a fuel nozzle and air is provided around the fuel nozzle. Fuel and gas are mixed to produce a combustible mixture which subsequently is passed through the burner body and ignited to produce a burner flame that, in the case of a water heater is applied to the a heat exchanger of the boiler.
Conventional premixed fuel burner assemblies produce short flames that are just beyond or above the burner porting area. Normally the mixture has 30 percent excess air so as to provide cleaner combustion products. At loadings (i.e. heat per unit area) below approximately 6 kilowatts per square decimeter, the burner port surface will be radiant since the velocity of the mixture is low resulting in the flame being positioned on or closely adjacent to the surface. This gives rise to problems of thermal fatigue and high temperature oxidation of the burner porting surface, and potential flashback of the flame into the burner body. At higher loadings (e.g. 12 kilowatts per square decimeter and above) the increase in volumetric flow is such that the velocity of the mixture may be increased to the point where the flame front is further from the burner porting surface resulting in a relatively cool porting surface. However, at high loadings if the amount of excess air is not or cannot be controlled, overheating of burner porting surface can still result when there is inadequate excess air (i.e. when there is too much fuel in the air/fuel mixture) since in such a case the flame will sit on the surface of the burner increasing the temperature. As is conventionally known, when the burner body becomes too hot (e.g. 2000 degrees Celcius) the fuel burner assembly can suffer failures, melting and irreversible damage.
Various types of fuel burner assemblies have been developed to attempt to maintain the flames above the surface of the outer cylinder by operating at high loadings (i.e. high fuel/air velocities) while at the same time maintaining a proper mix of fuel and flame stability. For example, U.S. Pat. No. 6,461,152 to Wood et al. discloses a tubular burner consisting of a cylindrical tubular body into which a distributor component can be fitted. The distributor is substantially the same axial length as the tubular burner body but of a smaller cross-sectional dimension than said body so to allow for easy insertion. The distributor divides the burner body into an upper and a lower chamber. The distributor has a first tubular portion and a second extension portion each of which is provided with axially aligned flanges having a number of perforations. While this assembly achieves a reasonable distribution of air and fuel streams prior to delivering the fuel/air mixture to the porting area of the tubular burner, the construction and assembly of this burner is expensive, as is the manufacture of the various components involved in the construction.
The invention provides in one aspect, a premixed fuel burner assembly, comprising:
The invention provides in another aspect, a method of making a fuel burner assembly, said method comprising the steps:
Further aspects and advantages of the invention will appear from the following description taken together with the accompanying drawings.
In the accompanying drawings:
Referring to
Burner body 12 is a hollow cylindrical tube having preferably having a circular cross-section. However, it should be understood that burner body 12 could also have various shaped cross-sections (e.g. oval, rectangular, polygon, etc.) depending on the particular use of burner body 12. For example, in the case where burner body 12 has an oval cross-section, the height of the combustion chamber can be minimized by orienting the minor axis in the vertical direction. Burner body 12 has a longitudinal axis A and is axially aligned with venturi tube 14 and distribution plate 16 as will be described. Burner body 12 is closed at one end 20 and open at the other end 22. The closed end 20 and open end 22 are formed using conventionally known crimping techniques. The open end 22 is adapted to receive and mount one end of venturi tube 14 and distribution plate 16 as will be described The closed end of burner body 12 is closed so that burning is confined within burner body 12. It should be understood that burner body 12 may be manufactured out of any high temperature resistant metal (e.g. stainless steel, aluminized steel, coated steel, etc.) Finally, burner body 12 should be understood to be any burner having an outer surface that defines an internal cavity in which venturi tube 14 and distribution plate 16 can be disposed.
As shown, the surface of burner body 12 includes a porting area 17 within which are formed a plurality of burner ports 18. Burner ports 18 consist of a plurality of small radially oriented rectangular slots arranged in an offset manner as shown. Burner ports 18 keep the flame front 50 (
Referring to
The exterior surface of venturi tube 14 where it enters the combustion chamber is sealed using an end cap 42. Flange 41 (
Referring to
The exterior surface of flanges 24 and 26 of distribution plate 16 are coupled to the inside surface of burner body 12 using an appropriate conventionally known welding technique (e.g. spot welding or seem welding techniques). Flanges 24 and 26 are coupled to the inside surface of burner body 12 such that that the mid-section 26 of distribution plate 16 is positioned underneath the longitudinal porting area 17 of burner body. Specifically, distribution plate 16 is positioned within burner body 12 such that the plane defined by the holes 28 within mid-section 26 of distribution plate is oriented along and collinear with the longitudinal axis of burner body 12 and such that holes 28 are positioned adjacent the burner ports 18 within porting area 17.
Holes 28 on distribution plate 16 are of variable size. The size of each hole 28 varies according to its position on distribution plate 16. Specifically, holes 28 are largest at one end of distribution plate 16 and smallest at the other end. The end at which holes 28 are the largest is intended to be located at the open end of fuel burner assembly 10 and the end at which holes 28 are smallest is intended to be located at the closed end 20 of fuel burner assembly 10. Preferably, holes 28 are one of two sizes, where larger sized holes 30 clustered at the open end 22 and a small sized holes 32 which extend the length from the end of the cluster of the larger sized holes 31 until the closed end 20. It should b understood that while only two sizes of holes ar shown and described, any form of gradient of hole size is contemplated. Specifically, in between the ends of distribution plate 16, holes 28 can be gradually reduced in size as they traverse from the open end 22 of fuel burner assembly 10 to the closed end of fuel burner assembly 10. Further, various patterns or configurations of holes 28 are also contemplated depending on the particular functionality required by a particular application.
The holes 28 within distribution plate 16 allow for improved mixing of fuel and air between the distribution plate 16 and the inside surface of burner body 12 (i.e. “mixing chamber D” as shown in
Accordingly, fuel burner assembly 10 is designed to maintain flames above the surface of burner body 12 by operating at high loadings (i.e. high fuel/air velocities) while at the same time maintaining a proper mix of fuel and flame stability. Fuel burner assembly 10 achieves these features through the use of a particularly perforated distribution plate 16 (i.e. variable sized holes 28) as discussed in conjunction with a partially extending venturi tube to optimize the mixing process between fuel and air streams.
As will be apparent to persons skilled in the art, various modifications and adaptations of the structure described above are possible without departure from the present invention, the scope of which is defined in the appended claims.
This application claims the benefit under 35 U.S.C. 119(e) of U.S. Provisional Application No. 60/442,514, filed Jan. 27, 2003.
Number | Date | Country | |
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60442514 | Jan 2003 | US |