1. Field of the Invention
This invention relates to a nozzle configured to control the flow of particles. More particularly this invention relates to a nozzle capable of regulating the velocity of particulate matter through the nozzle and the spray pattern of the particulate matter from the nozzle.
2. Background of the Invention
Many types of nozzles exist for conveying blown particulate matter from one medium into another. An exemplary application of a nozzle is in the combustion industry where it is desired to transfer combustible particles from a processing site to a combustion site. However, oftentimes the nozzle blows the combustible particles towards the walls of the combustion site, upon which the particles combust on or in close proximity to the walls, and thereby cause heat damage to the walls. Accordingly, what is needed is a nozzle designed to control the flow and/or spray of combustible particles such that the particles combust before they come in proximity to the walls of the combustion site.
The above-discussed and other drawbacks and deficiencies of the prior art are overcome or alleviated by a nozzle which controls the spray pattern and the distribution of particles as they enter into and are dispersed in a combustion chamber, wherein a combustion chamber is defined as any material burning site, such as a boiler, burner, furnace, and the like. The nozzle comprises a receiver in communication with a vortex chamber, which in turn is in communication with a discharge hood. The vortex chamber and the discharge hood are designed to reduce the air pressure within the nozzle, and to thereby decrease the velocity at which particles move through the nozzle. The nozzle further comprises a plurality of blades disposed on the vortex chamber which serve to control the spray pattern of the particles. The nozzle further optionally comprises a plurality of deflectors located on the discharge hood which further controls the spray pattern of the particles.
Disclosed herein is a nozzle which directs the speed and flow of particles. The nozzle is more particularly described with reference to the figures, however, the disclosure is not to be limited to the embodiments shown in the figures, but is intended to include all obvious and natural variations and modifications thereof as would occur to one of ordinary skill in the art.
Referring to the figures, an exemplary nozzle 10 comprises a receiver 11 connected to a truncated conical vortex chamber 12, and a truncated conical discharge hood 14 integrally connected to vortex chamber 12. Both of vortex chamber 12 and discharge hood 14 are tapered such that the widest end of vortex chamber 12 connects to the narrowest end of discharge hood 14. The narrowest end of discharge hood 14 is located at inner edge 24 and the widest end of discharge hood 14 is located at outer edge 26, wherein inner edge 24 and outer edge 26 define the outer limits of discharge hood 14. Discharge hood 14 of nozzle 10 is designed to further reduce the air pressure initially introduced into nozzle 10 and also to assist in determining the diameter of the combustion flame and spray pattern of the particles being combusted.
Nozzle 10 further comprises a plurality of blades 16 located on an interior side of vortex chamber 12. In an exemplary embodiment, blades 16 extend along all or a substantial portion of the length of the interior side of vortex chamber 12, wherein “substantial portion” comprises over about 80 percent of the length of the interior side of vortex chamber 12. In an exemplary embodiment, the terminal ends of the blades 16 are welded onto the interior side of vortex chamber 12. Each of blades 16 comprises a helical configuration so as to produce a centrifugal force inside nozzle 10 when in operation. As such, when in position, each of the blades overlaps and/or under laps at least one of the other blades. Although
An optional feature of the nozzle of the present invention is the integration of a plurality of deflectors 18 onto an interior surface of discharge hood 14. When used, plurality of deflectors 18 assists in fine tuning the particle mixture and spray pattern of the particles emitted through nozzle 10. Each of deflectors 18 may vary in size and shape depending on the application and on the design of the combustion chamber.
Nevertheless, in an exemplary embodiment, each of deflectors 18 comprises a cavity 20 surrounded by a shell 22 attached to the interior surface of discharge hood 14. In an exemplary embodiment, each of shell 22 comprises a truncated conical configuration. Additionally, in an exemplary embodiment, shells 22 are welded onto discharge hood 14. Additionally, shells 22 taper such that the narrowest ends of shells 22 are directed towards, and preferably meet at, inner edge 24 of discharge hood 14, and the widest ends of shells 22 are directed towards, and preferably meet, at outer edge 26 of discharge hood 14. In an exemplary embodiment, each of shells 22 may be formed from about a 13 inch long and about a 2 inch wide solid stainless steel, or other corrosion resistant alloy, pipe 28. Pipe 28 may be bored through to form the desired truncated conical structure. Although six individual deflectors are depicted, it is contemplated that any number may be used to accomplish the purpose of directing the spray of particles out of the nozzle.
Nozzle 10 further comprises a mount 30 surrounding the outer periphery of nozzle 10. Mount 10 is preferably located at the point where vortex chamber 12 and discharge hood 14 meet. Mount 30 comprises a plurality of vias 32, wherein nails or screws may be inserted through vias 32 to further secure nozzle 10 onto a desired structure. Of course, fastening elements other than vias may be used to attach the nozzle to the desired structure so long as the structure to which the nozzle is mounted comprises complementary fastening elements.
Exemplary materials for forming the nozzle include stainless steel and other non-corrosive alloys, such as hastelloy®. The Example provided below describes exemplary measurements for forming the nozzle as described herein. However, it is noted that the size and taper of the nozzle may be varied based on the size of, for example, a combustion chamber, boiler, or furnace.
Referring to
An exemplary application of the nozzle described herein is in the transport of particles into a combustion chamber. In this application, it is envisioned that the particles enter the nozzle through the receiver under a pressure of about 1.3 pounds per square inch (“psi”). As the vortex chamber is tapered, the pressure at the widest end of the vortex chamber is less than that at the narrowest end. Accordingly, the velocity of the particles as they move through the length of the vortex chamber and into the discharge hood lessens. This is particularly important in the present application as it is desired to combust or to burn the particles as close as possible in the center of the combustion chamber. Where combustion occurs too close to the walls of the combustion chamber, a high amount of heat energy is more likely to contact the walls of the combustion chamber, thereby increasing the likelihood of damage to the walls. To accomplish burning towards the center of the combustion chamber, the velocity in which the particles are emitted from the nozzle into the combustion chamber is slowed. Such reduction in velocity is accomplished by reducing the amount of pressure within the vortex chamber, which, as previously stated, is accomplished by gradually increasing the internal diameter of the vortex chamber towards the discharge hood.
In this application, the particles may be blown into the vortex chamber by a pressurized flow of air. For example, the particles may be blown through a supply pipe, which is connected to the receiver. As the particles are blown through the vortex chamber and make contact with the plurality of blades, a centrifugal force is generated which assists in spreading the particles in the combustion chamber as desired.
The size and pitch of the plurality of blades inside the vortex chamber will vary based on the application. However, the construction and dimension is determined such that the particles emitted from the nozzle are sprayed in a desired pattern to create a desired flame size and length. The design and the arrangement of the plurality of blades preferably cause centrifugal motion to blow the heavier particles to the edges of the combustion chamber so that the particles have a longer burn time. Therefore, the plurality of blades is designed to create centrifugal force inside the nozzle. This process allows the fuel to exit the nozzle in such a manner so as to spread the particles in the combustion chamber as desired. The larger fuel particle sizes are ejected out of the nozzle at the outer perimeter of the nozzle which provides for the longest period of time for combustion available.
Furthermore, the mount may be secured to the outer side walls of the combustion chamber or boiler such that the outer edge 26 of discharge hood 14 jets into the combustion burner. In this application, it is preferred that fire brick insulation is used to buffer the nozzle and the combustion chamber.
The nozzle of the present invention is particularly useful when used in cooperation with a dedensification and delivery unit (“DDU”) as described in U.S. application Ser. No. 11/160,061, and which is incorporated herein in its entirety, and which is used to prepare and burn specification raw materials as a fuel source. In this embodiment, the nozzle of the present invention may replace or constitute the low volume blower hose which connects the refining area to the combustion chamber. In this manner, then, the nozzle of the present invention can convey a dedensified alternative fuel source to a combustion chamber in a controlled manner.
As required, detailed embodiments of the present invention have been disclosed herein. However, it is to be understood that the disclosed embodiments are merely exemplary of the invention, which may be embodied in various forms. Therefore, specific structural and functional details disclosed herein are not to be interpreted as limiting, but merely as a representative basis for teaching one skilled in the art to variously employ the present invention in virtually any appropriately detailed structure.
This application claims the benefit of U.S. Provisional Application No. 60/595,794 filed on Aug. 5, 2005.
Number | Date | Country | |
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Parent | 60595794 | Aug 2005 | US |
Child | 11461645 | Aug 2006 | US |