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The present invention relates to boiler systems that employ combustion processes and, more particularly, to improved boiler systems for hot water and steam applications and associated methods of operation.
Boiler systems that employ combustion processes to generate heat are commonly employed in a variety of environments. Fire tube boilers or boiler furnaces typically have a combustion chamber encompassed within a vessel or water tank and a plurality of heat transfer tubes passing through the vessel for conducting heated or hot combustion gases resulting from combustion of an air-fuel mixture by a burner, typically located at the front of the boiler. The hot combustion gases are typically passed from the front of the boiler, to the rear, and back to the front. Additional passes, using additional tubes, are often provided within the boiler to accomplish complete heat exchange.
In other systems, multiple combustion stages, particularly by using multiple combustion chambers, are used to accomplish complete combustion. For example, see U.S. Pat. No. 6,971,336, which teaches a firetube boiler furnace having two combustion sections and an in-line intermediate tubular heat transfer section between the two combustion sections and integral to the pressure vessel. This design provides a staged oxidant combustion apparatus with separate in-line combustion chambers for fuel-rich primary combustion and fuel-lean secondary combustion and sufficient cooling of the combustion products from the primary combustion such that when the secondary combustion oxidant is added in the secondary combustion stage, the NOx formation is less than 5 ppmv at 3% O2.
It has been found the prior systems, such as the kind noted above, while capable of providing benefits, also can have drawbacks, including significant complexity, and relatively high costs of production, installation and/or maintenance. Moreover, such prior systems can take up a rather large area, or “footprint,” and have a relatively large size, creating complexity at during installation, particularly in instances in which space is limited and/or access is difficult.
In view of one or more such limitations that exist in relation to conventional fire tube boiler systems, it would be advantageous if improvements could be achieved in relation to such boiler systems and related methods of operation.
The present disclosure, in at least some embodiments, relates to a boiler system that includes a burner and a housing having a generally cylindrical shape and extending between first and second walls to provide a generally cylindrical space. Further, a fire tube is positioned near a bottom of the generally cylindrical space the fire tube and extends longitudinally from a first wall of the cylindrical housing to a fire tube end wall, with the fire tube providing a combustion chamber where combustion of an air-fuel mixture is accomplished using the burner. Additionally, a first set of tubes is located within the housing, with the tubes of the first set extending longitudinally from and parallel with the end of the fire tube to the second wall of the housing, and a second set of tubes is located above and about a portion of the fire tube and a portion of the first set of tubes, with the tubes of the second set of tubes generally spanning a length extending between the first and the second walls of the cylindrical housing. A chamber providing a space between and connecting the first and second sets of tubes is provided as well, and heated or hot combustion gases flow from the fire tube to the first set of tubes, through the chamber space, and to the second set of tubes. The boiler system can be configured for use with steam and hot water applications.
Other embodiments are contemplated and considered to be within the scope of the present disclosure.
Features of the present disclosure which are believed to be novel are set forth with particularity in the appended claims. Embodiments of the disclosure are disclosed with reference to the accompanying drawings and are for illustrative purposes only. The disclosure is not limited in its application to the details of construction or the arrangement of the components illustrated in the drawings. The disclosure is capable of other embodiments or of being practiced or carried out in other various ways. Like reference numerals are used to indicate like components. In the drawings:
Extending longitudinally (and as shown horizontally) of the boiler 10 and generally mounted within the shell 12 and generally near its bottom 28 is a main or fire tube or furnace 30, which provides a combustion chamber 32 (
At or near its front end wall 35, the fire tube 30 opens to accommodate a burner 50 (
Also extending longitudinally (and as shown horizontally) of the boiler 10 is a second set of tubes, generally referenced by numeral 44, located generally above the fire tube 30 and above the first set of tubes 40, and generally span a length extending from the inner rear end wall 26 to the inner front end wall 20. Moreover, the second set of tubes 44 are open to a space forward of the front inner end wall of the boiler, generally referenced by number 46 (
In accordance with at least some embodiments, the shell structure 34 of the furnace 30 is centered with respect to the housing 12 of the boiler system 10 with respect to a vertical plane P, and the tubes of the first set of tubes and the tubes of the second set of tubes are symmetrically positioned with respect to the vertical plane P. Moreover, in accordance with at least some embodiments, the shell structure 34 of the furnace 30 is positioned with respect to the housing 12 of the boiler system 10 such that the shell structure of the furnace, and all of the tubes of the first set of tubes 40 are below a horizontal plane H of the housing 12 of the boiler system 10. Finally, the tubes of the second set of tubes are circumferentially disposed about the shell structure of the furnace (and therefore the tubes of the first set of tubes) such that they are located above a horizontal plane Hf of the shell structure 34 of furnace 30. The second set of tubes 44 is disposed symmetrically with respect to the vertical plane P of the boiler housing 12 of the boiler 10.
The burner 50 (
In at least some embodiments, and as shown (in
In a further embodiment, as shown in
Also as shown, with reference to
In accordance with embodiments of the present disclosure, the main or fire tube 30/30′ provides for complete combustion of heated gases, as well as passage of such heated gases to the first set of tubes 40/40′ rearward of the fire tube, with such passage or flow indicated by arrows 66/66′. The first set of tubes 40/40′ provide for further passage of the heated gases to the turnaround space 42/42′, with such flow indicated by arrows 67/67′ and then to the second set of tubes 44/44′ located, as shown, above or vertically in relation to the first set of fire tubes, which such flow indicated by arrows 68/68′. The second set of tubes provide for further passage of heated gases in to the space 46/46′, and then to the exhaust 48/48′, as indicated by arrows 70/70′, where the gases are discharged, as indicated by arrows 72/72′.
As shown in
With reference to these Figures, the boiler 10″/10′″ employs, in accordance with at least some embodiments, a housing or shell 12″/12′″ with, as shown in the present embodiment, a generally cylindrical shape, and includes a circumference, and is mounted upon an appropriate base structure 14″/14′″. At or near its front end 16″/16′″ (
Extending longitudinally (and as shown horizontally) of the boiler 10″/10′″ and generally mounted within the shell 12″/12′″ and generally near its bottom 28″/28′″ is a main or fire tube or furnace 30″/30′″, which provides a combustion chamber 32″/32′″ (
At or near its front end wall 35″/35′″, the fire tube 30″/30′″ opens to accommodate a burner 50″/50′″ (
Also extending longitudinally (and as shown horizontally) of the boiler 10″/10′″ is a second set of tubes, generally referenced by numeral 44″/44′″, located generally above the fire tube 30″/30′″ and above the first set of tubes 40″/40″, and generally span a length extending from the inner rear end wall 26″/26′″ to the inner front end wall 20″/20′″. Moreover, the second set of tubes 44″/44′″ are open to a space forward of the front inner end wall of the boiler, generally referenced by number 46″/46″′ (
In accordance with at least some embodiments, the shell structure 34″/34″ of the furnace 30″/30′″ is centered with respect to the housing 12″/12′″ of the boiler system 10″/10′″ with respect to a vertical plane P″/P′″, and the tubes of the first set of tubes and the tubes of the second set of tubes are symmetrically positioned with respect to the vertical plane P″/P′″. Moreover, in accordance with at least some embodiments, the shell structure 34″/34″′ of the furnace 30″/30′″ is positioned with respect to the housing 12″/12′″ of the boiler system 10″/10′″ such that the shell structure of the furnace, and all of the tubes of the first set of tubes 40″/40′″ are below a horizontal plane H″/H′″ of the housing 12″/12′″ of the boiler system 10″/10′″. Finally, the tubes of the second set of tubes are circumferentially disposed about the shell structure of the furnace (and therefore the tubes of the first set of tubes) such that they are located above a horizontal plane Hf″/Hf′″ of the shell structure 34″/34′″ of furnace 30″/30′″. The second set of tubes 44″/44′″ is disposed symmetrically with respect to the vertical plane P″/P′″ of the boiler housing 12″/12′″ of the boiler 10″/10′″.
The burner 50″/50′″ (
In accordance with these embodiments, the respective boiler systems 10″/10′″, respectively, are provided for use with a hot water application. Accordingly, it is contemplated that the boilers 10″/10′″, and particularly each of the respective shells 12″/12′″, are completely, or at least substantially completely filled (or “flooded”) with water 74 during operation, and so no level of water is indicated, as was shown in
With further reference to
One burner type or style that is contemplated for use, or contemplated to be adapted for use, in regard to embodiment(s) of the boiler 10/10′/10″/10′″ of the present disclosure is the XPO™ Indirect burner, available from Maxon Corporation, located at 201 East 18th Street, Muncie, Ind. 47302. In such embodiments, various features of the burner 50/50′/50″/50′″ can take a specific form, for example, the burner head 52/52′/52″/52′″ can take the form of an air-fuel nozzle. Additional details regarding at least some embodiments of burners, such as the XPO™ Indirect burner, that can be used in accordance with at least some embodiments of the present disclosure are provided in U.S. Pat. No. 8,784,096, entitled “Low NOx Indirect Fire Burner”, the entirety of the teachings of which are incorporated by reference herein. In other embodiments, the burner 52/52′/52″/52′″ can take on other styles or forms, for instance a burner of the fiber mesh style (not shown), where the burner head can take the form of a burner canister, or surface burner.
In accordance with embodiments of the present disclosure, it is contemplated that the tubes making up the first and second sets of tubes 40/40′/40″/40′″ and 44/44′/44″/44′″, respectively, can comprise any of a variety of tubes including by way of example, plain tubes, plain tubes with extended heating surface, and rifled tubes that are generally known. One example of rifled tubes currently available and known is X-ID® tubes, available from Tektube, located at 555 West. 41st Street, Tulsa, Okla., 74107. Another example of tubes suitable for use in relation to embodiments of the present disclosure are aluFer® tubes, available from Hoval Aktiengesellschaft Austrasse 70, 9490 Vaduz Liechtenstein. In at least some embodiments, the tubes can comprise cylindrical smooth outer-walled outer tubes of steel into which profiled inserts made of aluminum, and having ribs, may be inserted, such as of the kind described in a in U.S. Pat. No. 6,070,657, entitled “Heat Exchanger Tube for Heating Boilers”, the entirety of the teachings of which are incorporated by reference herein. In other embodiments, it is contemplated that the tubes can take on other styles or forms. Other tube types are contemplated and considered within the scope of the present disclosure.
In accordance with embodiments of the present disclosure, and as noted above with references to the Figures, tubes of the second set of tubes 44/44′/44″/44′″ are circumferentially disposed about the shell structure 12/12′/12″/12′″ of the furnace 30/30′/30″/30′″ (and therefore the tubes of the first set of tubes 40/40′/40″/40′″) such that they are located above a horizontal plane Hf/Hf′/Hf″/Hf′″ of the shell structure 34/34′/34″/34′″ of furnace 30/30′/30″/30′″. It is of further note that, as the boiler horsepower increases (e.g., up to 800 horsepower), it has been found that, in at least some embodiments, the number of tubes also increases and the boiler is packed much tighter with tubes, or stated another way, the spacing between respective tubes is more compressed. Moreover, it has been found that at least some of the tubes of the second set of tubes 44/44′/44″/44′″ on such larger horsepower boilers are located below the horizontal plane Hf/Hf′/Hf″/Hf′″ and may be considered as being located below a portion the fire tube.
Advantageously, disclosed in accordance with at least some embodiments of the present disclosure, is a means for providing a boiler system with a reduced size while maintaining efficiency. In accordance with at least some embodiments, the boiler comprises a tank for a supply of water to be heated. Within the lower portion of the tank, a combustion chamber is provided, having a burner assembly mounted at one end. The chamber is terminated short of the opposite end of the water tank and has a series of smoke or fire tubes to direct the combustion products through the water to a manifold at the tank end. The manifold directs the combustion products back through tubes into the water tank, generally mounted about the combustion chamber, to an exhausting manifold at the burner end of the tank.
Advantageously, the boiler and/or the burner-boiler system, when compared to conventional systems, has a reduced size or “footprint,” and so is better suited for a smaller boiler room, or other location where space is a substantial constraint.
Boiler systems provided in accordance with embodiments of the present disclosure, achieve 9 ppmv NOx formation at 3% O2. In still further embodiments, the system achieves 5 ppmv NOx at 3% O2.
Moreover, boiler systems provided in accordance with the present disclosure do not require two (or multiple) combustion stages or sections in order to accomplish complete combustion of the air-fuel mixture, let alone such two (or multiple) sections having one zone that may be considered as “fuel rich” and another that may be considered as “fuel lean.”
A boiler system may comprise two or more embodiments described herein. Any reference to orientation (e.g., horizontal, vertical, upper, lower, front, rear, and the like) is made with reference to the specific drawing for teaching purposes only and should not be considered limiting.
In accordance with at least some embodiments of the present disclosure, a boiler system is provided that comprises: a burner; a housing having a generally cylindrical shape and extending between first and second walls to provide a generally cylindrical space; a fire tube positioned near a bottom of the generally cylindrical space the fire tube and extending longitudinally from a first wall of the cylindrical housing to a fire tube end wall, the fire tube providing a combustion chamber where combustion of an air-fuel mixture is accomplished using the burner; a first set of tubes located within the housing and extending longitudinally from and parallel with the end of the fire tube to the second wall of the housing, and a second set of tubes located above and about a portion of the fire tube and a portion of the first set of tubes, the second set of tubes generally spanning a length extending between the first and the second walls of the cylindrical housing; and a chamber providing a space between and connecting the first and second sets of tubes; and wherein heated combustion gases flow from the fire tube to the first set of tubes, through the chamber space, and to the second set of tubes.
In accordance with at least some embodiments of the present disclosure, the fire tube includes a shell structure comprising a generally cylindrical shape having a circumference and the first set of tubes extends in-line with the fire tube.
In accordance with at least some embodiments of the present disclosure, the housing includes a circumference and the second set of tubes extends at least partially about the shell structure.
In accordance with at least some embodiments of the present disclosure, a vertical plane passing through a center of the housing also passes through a center of the fire tube and the first and second sets of tubes are each positioned generally symmetrically on either side of the vertical plane.
In accordance with at least some embodiments of the present disclosure, at least one of: (a) none of the tubes of the second set of tubes extend in a region or location that is below any portion of the fire tube, and (b) none of the tubes of the second set of tubes extend in a region or location that is below any portion of the tubes of the first set of tubes.
In accordance with at least some embodiments of the present disclosure, none of the tubes of the second set of tubes extend in a region or location that is between the fire tube and the bottom of the cylindrical housing.
In accordance with at least some embodiments of the present disclosure, the flow of heated combustion gases is sequential such that the heated gases flow from the fire tube directly to and through the first set of tubes, and then directly to and through the chamber space, and then directly to and through the second set of tubes, before the heated combustion gases are discharged from the boiler.
In accordance with at least some embodiments of the present disclosure, the second set of tubes and the first set of tubes are submerged in water.
In accordance with at least some embodiments of the present disclosure, either: (a) water is provided within the housing to a water level, providing space open space to remain within the housing and permitting the boiler to be configured for steam applications; or (b) water is provided within the housing so that the housing is filled with water and the boiler is configured for hot water applications.
In accordance with at least some embodiments of the present disclosure, the first set of tubes comprises one or more plain tubes, one or more plain tubes with an extended heating surface, or one or more rifled tubes, and where in the second set of tubes comprises one or more plain tubes, one or more plain tubes with an extended heating surface, or one or more rifled tubes.
In accordance with at least some embodiments of the present disclosure, the burner is integrated with respect to the fire tube.
In accordance with at least some embodiments of the present disclosure, the burner is integrally formed with the housing.
In accordance with at least some embodiments of the present disclosure, combustion of the air-fuel mixture is completed within the combustion chamber, which is the only combustion chamber.
In accordance with at least some embodiments of the present disclosure, the air provided with for use with the air-fuel mixture is provided from a single source.
In accordance with at least some embodiments of the present disclosure, there is no device provided within the chamber providing the space between and connecting the first and second sets of tubes, that is configured to close any portion or end of any of the tubes in the first set of tubes or any of the tubes in the second set of tubes.
In accordance with at least some embodiments of the present disclosure, there is no device provided within the chamber providing the space between and connecting the first and second sets of tubes, that is configured to reverse the flow of any portion of the heated gases in any of the tubes in the first set of tubes, or any of the tubes in the second set of tubes.
Notwithstanding the above description, it should be appreciated that the present disclosure is intended to encompass numerous other systems, arrangements, and operational processes in addition to those descripted above. In reference to the preceding paragraphs and the aforementioned figures, although various embodiments of the present invention have been described above, it should be understood that embodiments have been presented by way of example, and not limitation. A person of ordinary skill in the art will recognize that there are various changes that can be made to the present invention without departing from the spirit and scope of the present invention. Therefore, the invention should not be limited by any of the above-described example embodiments, but should be defined only in accordance with the following claims and equivalents of the claimed invention presented herein.