US3060903A - Vapor generator - Google Patents

Description

Oct. 30, 1962 A. H. RUDD VAPOR GENERATOR Filed Jan. 25, 1960 2 Sheets-Sheet 1 GAS OUTLET N AIR INLET W ATTORNEY tees This invention relates to the art of vapor generation and vapor heating, and is more particularly directed to an improvement to that class of vapor generating and heating unit in which additional heating gases are introduced directly into the furnace or radiant heat absorption chamber thereof.

In the design of many of the larger high temperature and high pressure vapor generating and heating units control of the gas temperature, the gas mass flow through the unit, and the resultant vapor temperatures are effected by a recirculating gas system that withdraws partially cooled combustion gases from a position downstream, gasfiowwise, of the vapor heating section and effects the entry of the recirculated gases into the furnace chamber where it com-mingles with the gaseous combustion products.

In such units, recirculated gases are directed to a duct which extends transversely along a tubular wall portion of a fluid cooled furnace chamber, the recirculated gases being discharged from the duct directly into the furnace chamber through port openings formed by the displacement of alternate or spaced tubes forming the furnace wall in the vicinity of the duct. The recirculated gases thus introduced into the furnace have the effect of controlling slagging and/or maintaining a predetermined steam temperature. This is attained in part by the recirculated gases effecting either a reduction in the heat transfer to the heat absorption surfaces of the furnace wall tubes or a reduction in the gas temperature leaving the furnace chamber, and in part by effecting an increase in the gas mass flow over the convection heating surfaces of the unit.

Inasmuch as the recirculated gases are oftentimes introduced through port openings located in the high temperature zone of a furnace, experience has indicated the necessity for protecting the inside surfaces of the gas recirculating duct in the vicinity of the furnace walls from the high temperature radiant emission of the furnace gases radiating through the port openings. Heretofore, high temperature insulation, secured by pin studs, was used on the inside of the duct to withstand the deleterious effects of the direct radiation emanating from the adjacent furnace chamber. The use of such insulation increased the initial capital expenditure for such duct work in addition to creating a condition which required continuing maintenance.

In furnaces fired by slag forming fuels, a further difficulty was encountered in that gas discharge ports of the known constructions, had a tendency to become slagged over and thus rendered inoperative. This condition was particularly aggravated at ratings on the unit, when little, or no, recirculated gases are introduced into the furnace to discourage the accumulation of slag across the port opening.

An object of this invention is to overcome the abovementioned difficulties by providing a duct arrangement operatively associated with a wall portion of the radiant 336,903 Patented cf. 30, 1962 ice furnace chamber, wherein the ports through which the recirculated gases are introduced into the furnace are defined by portions of the furnace wall tubes arranged to effect a highly efficient shield in the vicinity of the port opening to protect the interior of the duct from the destructive radiant heating effects emanating from the adjacent furnace chamber.

Another object of this invention is to provide a gas recirculating system with novel discharge gas port construction, arranged and constructed in a manner to minimize the tendency for slag to accumulate and seal the port opening, particularly during operation of the unit when little or no recirculated gases are flowing therethrough.

Another object of this invention is to provide a port construction having a relatively low resistance to gas flow therethrough.

The above objects and other features are attained by a recirculating gas system which includes a duct that extends transversely along a Wall portion of the unit setting so that an upright portion of the generating tubes defining the wall portion of the setting or furnace chamber forms a wall portion of the duct through which the recirculated gases are directed to the furnace. According to this invention, a plurality of tubes which define the common wall between the duct and adjacent radiation chamber are bent outwardly of the setting and into the duct to define openings at spaced intervals along the Width of the Wall through which the recirculated gases are discharged directly from the duct into the furnace. The adjacent outwardly bent tubes are progressively displaced laterally so as to fan outwardly on either side of the center line of the port to form a radiation shield spaced inwardly of the duct. The portions of the tubes so displaced form a fluid cooled radiation shield to protect the interior of the duct from the deleterious effects of direct radiation emanating from the adjacent furnace chamber. Bafile means are disposed between adjacent laterally displaced tube portions of the radiation shield to close spaces existing therebetween so that a substantially imperforate shield is formed encompassing the area of the port opening.

A feature of this invention resides in the provision that the amount of insulation required on the interior of the duct discharging the recirculated gases into the furnace may be substantially reduced, thereby decreasing the initial capital outlay, and also greatly reducing the amount of future maintenance which would otherwise be required to maintain the duct in proper operating condition.

The various features of novelty which characterize the invention are pointed out with particularity in the claims annexed to and forming a part of this specification. For a better understanding of the invention, its operating advantages and specific objects attained by its use, reference should be had to the accompanying drawings and descriptive matter in which is illustrated and described a preferred embodiment of the invention.

In the drawings:

FIG. 1 is a vertical sectional view of a vapor generating and heating unit embodying the invention.

FIG. 2 is a plan section taken along line 2-2 of FIG. 1.

FIG. 3 is a sectional view taken alongline 33 of FIG. 2.

Referring to the drawings, the invention herein described is illustrated in conjunction with a high capacity, high pressure and high temperature natural circulation steam generating andheating unit 10. Generally, the unit comprises a setting 11 which includes a verticallyelongated furnace 12, a laterally extending gas pass 13 connected adjacent the upper end of the furnace, and a downwardly extendingconvection heating section 14 serially connected with the gas pass 13.

Thefurnace 12 is defined by upright front, rear andside walls 15, 16 and 17, respectively. The front wall includes a row of steam generating tubes 13 which extend upwardly from a lowerwater supply drum 1?. As shown,tubes 18 first extend along thebottom 18A of the furnace thence upwardly along the front wall of the furnace. Aportion 18B of thefront wall tubes 18 defines the throat portion of thecyclone furnaces 20 which generate the gaseous products of combustion that are discharged into thefurnace 12. Thefront wall 15 at anintermediate portion 15A of the furnace immediately above the cyclone furnace level is inclined outwardly and upwardly to define with the adjacent side and rear walls an intermediate or transitionradiant furnace chamber 12A. Beyond this transition section, thefront wall tubes 18 extend upwardly and connect with the steam andwater separating drum 21 of the unit. Therear wall 16 includes a row ofsteam generating tubes 22 which extend upwardly from thesupply drum 19 to an upper rear wall header 23, the latter in turn being connected bysuitable connectors 24 to thesteam drum 21. A portion of therear wall tubes 22 immediately below the furnace outlet 25, which connects with the lateral gas pass 13, is inwardly bent to define a nose arch 2 6. Theopposed side walls 17 of the furnace each include a row of generating tubes 2'7 extending between their respective lower and upperside wall headers 28 and 29, respectively. Each of theside wall headers 28, 29 in turn is connected into the circulation system of the unit by suitable conduits '30, 31 connecting to thesupply drum 19 andmain steam drum 21, respectively.Portions 27A of theside wall tubes 27 adjacent the upper end of the setting are laterally displaced to define the side walls of the lateral 'gas pass 13.

Thetubular Walls 18, 22 and 27, thus define a verticallyelongated furnace 12 which has a relatively small lower or primary radiation chamber 128 which forms a chamber common to each of thecyclone furnaces 20. The lower segments of the tubularwalls defining chamber 12B are preferably covered with suitable high heat resistantrefractory material 12D. Thelower chamber 12B is open at its upper end and is connected by thetransition chamber 12A, formed by the upwardly divergingportion 15A of thefront wall 15 to an upper superposedsecondary radiation chamber 12C.

A plurality of cyclone furnaces 20 of the general construction as disclosed in US. Patent No. 2,357,301 generate the gaseous products of combustion which flow upwardly through thefurnace 12. Whilecyclone furnaces 20 are herein illustrated as the means employed for generating the gases of combustion, it is to be understood that other burner means may be equally suitable for firing the unit in accordance with this invention.

In the illustrated form, FIG. 1, thecyclone furnaces 20 are arranged in superposed position and are adapted to be independently fired by relatively low quality, high ash content, coarsely pulverized or granulated coal. Each of thecyclone furnaces 20 is arranged to separately discharge the hot products of combustion and molten slag directly into thelower chamber portions 12B, wherein the gases of the several cyclones are thoroughly mixed.

Each of thecyclones 20 is substantially circular in cross-section, and the barrel portion 20A thereof is defined by steam generating tubes which together with thefront wall tubes 18,rear wall tubes 22 andside wall tubes 27 constitute the steam generating circuits of the unit. The generating unit shown is of the natural circulation type with feedwater being supplied to theupper drum 21. Downcomers 30A connect the steam andwater drum 21 to the lowerwater supply drum 19 which feeds the individual steam generating circuits.

The steam generated in each of the wall circuits during operation of the unit is delivered to thesteam drum 21 and is separated therein. Saturated steam from thesteam drum 21 is then superheated by flowing through suitable steam heating surfaces which are disposed in heat transfer relationship to the heating gases flowing through the unit.

As shown, thewalls 31, 32 and opposed connectingside Walls 33 defining the convection section or bird cage" 14 are lined with steam cooling tubes. Saturated steam is delivered from thesteam drum 21 throughsteam conduits 34 to a collecting header 35. From the collecting header 35, the steam flows through a row offurnace roof tubes 36 to a distributingheader 37.

The distributingheader 37 in turn supplies steam to each of the tubular wall circuits defining thewalls 31 and 32, and byconnectors 37A toside walls 33 of theconvection gas pass 14, the circuits terminating in aring header 38 positioned in the lower portion of thechamber 14. From thering header 33 the steam flows serially through aprimary superheater 39. As shown, theprimary superheater 39 comprises a plurality of platen elements, each platen element being formed of multiple looped return bend tubes. Each of the primary superheater platens discharges into theoutlet header 40.

From the primary superheater outlet header 4!) the steam flows serially through suitable conduit means 41 to the inlet header 42 of asecondary superheater 43 wherein the steam is finally superheated.

Thesecondary superheater 43 comprises a plurality of transversely spaced platen elements formed of vertically depending tubes disposed adjacent the furnace outlet 25. The steam flowing therethrough is discharged to anoutlet header 44 from whence the finally superheated steam is delivered to a point of use through conduit 45. Aneconomizer 46 for preheating the feedwater supplied to the drum is located in thedownfiow pass 14 beyond thesuperheater 39.

In accordance with this invention the gas flow is generally upwardly through thefurnace chamber 12, thence laterally through the lateral gas pass 13 and thence downwardly through the convection heating section ordownfiow pass 14 from whence the gases are directed through anair heater 47 to a suitable gas outlet orflue 48. If desired asteam reheater 70 comprising spaced platens of return bend tubes may be disposed in the gas pass 13.

In order to control the gas temperatures and/or gas mass flow through the unit to maintain and control superheat temperatures, it has been customary to withdraw a port-ion of the gases downstream gasflow-wise of theprimary superheater 39 and recycle the same through thefurnace 12.

In accordance with this invention the gas recirculation system for introducing additional heating gases into thefurnace 12 comprises aduct 49 for withdrawing a portion of the flue gases after they pass through theconvection heating section 14. The outlet end ofduct 49 connects with a fan orblower 50 which discharges the recirculating gases through anoutlet duct 51 to a manifold or distributingduct 52. As shown,duct 52 extends transversely along the furnace rearwall tube row 22.

Themanifold duct 52 comprises a sheet metal casing which defines the top 53, rear 54 and bottom 55 of the duct. The front face ofduct 52 is defined by that portion of water cooledtubes 22 of the furnace wall which are adjacent the duct.

As shown in FIGS. 1 and 2, theduct 52 extends transversely of the furnace at a position above the refractory lined portion of thelower furnace chamber 12B and is located adjacent the rear wall opposite theinclined wall portion 15A of the front wall. Therear wall tubes 22, in

the plane of the wall, are disposed in substantially tangent relationship as shown in FIGS. 2 and 3. In accordance with this invent-ion, and as shown in FIGS. 2 and 3, a plurality of adjacentupright tube portions 22A and 22H of therear wall tubes 22, in the vicinity ofduct 52 and located at spaced intervals along the length ofduct 55, are bent out of the plane of the Wall to defineport openings 56. The recirculated gases are thus discharged throughport openings 56 directly from theduct 52 into thefurnace 12 to mix with the combustion gases flow-ing upwardly therethrough.

As shown in FIGS. 2 and 3, portions oftubes 22A to 22H are bent outward of the furnace and inwardly within theduct 52.Tube groups 22A to 22D, and 22B to 22H, respectively, are grouped on either side of the center line ofport 55, the tubes of each group being laterally displaced to fan outwardly from the port center line a progressively increasing amount to a point beyond theport opening 56 to more eifectively shield the inside of the duct from radiation. In this manner the outermost orend tubes 22A and 221-1, which define the extreme limits of theopenings 55, are spaced rearwardly of the plane of therear wall tubes 22 and to one side of the port opening to define the entrance topassageways 56A, 56B which lead toport opening 56. Thepassageways 56A, 56B andopening 56 are sufiiciently large so as not to be easily closed or clogged by slag accumulations, even under the most adverse operating conditions, as for example during operation when little or no gas is being recirculated throughduct 52. Also the arrangement facilitates sizing of theport openings 56 so that a relatively low gas flow pressure drop therethrough is maintained. This feature is important where large quantities of recirculated gas are required.

In thespaces 58 formed by the lateral displacement oftubes 22A to 22H, there is disposed a baflle means 59 which substantially closesspaces 58. In the illustrated embodiment these baffle means 59 are formed by closely spacedfiat studs 60 welded to opposed surfaces of the tube as shown. The irregular portions ofspaces 58 formed where the tubes are bending back into the plane of the wall may be closed by appropriately shaped plates and/ or suitable refractory.

With this arrangement, thetubes 22A to 22H andstuds 60, defining theport construction 56 described, provide a highly elfective shield or bafile means disposed inwardly of the duct to protect the inner surfaces of theduct 52 from the harmful effects of direct radiation caused by the combustion of fuel in theadjacent furnace chamber 12. For this reason the amount and/ or quality of insulating material heretofore required to protect the interior of the ducts, can be substantially reduced.

Further, the curvature of the baflie wall or shield formed by the progressively displaced portion oftubes 22A to 22H, as shown in FIG. 2, streamlines the flow of gases through the port, particularly since they approach each other as indicated by the arrows, and thus minimizes the impact and promotes controlled introduction of the gases into the furnace. Thus the pressure drop through theport 56 tends to be minimized.

If desirable aretractable soot blower 61 may be located within eachport 56, as shown, the arrangement being such that when it is not in operation it is retracted withinduct 52 to protect it from furnace radiation.

While the location ofports 56 ofduct 52 are illustrated adjacent therear wall 22 of thetransition section 12A, it will be understood that location of theduct 52 and itsport openings 56 to attain the desired gas temperature and/or mass flow of any particular operating unit.

While in accordance with the provisions of the statutes there is illustrated and described herein the best form and mode of operation of the invention now known to the inventor, those skilled in the art will understand that changes may be made in the form of the apparatus disclosed without departing from the spirit of the invention covered by the claims, and that certain features of the invention may sometimes be used to advantage without a corresponding use of other features.

What is claimed is:

1. A furnace chamber within which combustion gases are generated and bounded in part by a wall including upright fluid cooled tubes, means for introducing low temperature heating gases into said furnace chamber to mix with the gases of combustion generated therein, said means including a duct extending transversely of and connected to said wall with said wall forming a common wall between said duct and said furnace, a group of consecutive tubes of said common wall having intermediate portions offset outwardly a substantial distince into said duct to provide an opening in said common wall and bent laterally in said duct relative to the centerline of said opening, with the intermediate tube portions near to the center line of the opening being outwardly offset from the plane of said common wall a lesser distance than the remaining intermediate tube portions, means for substantially closing the intertube spaces of said intermediate tube portions so bent to form a shield for the protection of said duct from radiation from said furnace, said shield and common wall cooperating to define a passageway of decreasing vertical cross-sectional area in the direction of gas flow therethrough arranged to discharge low temperature gases from said duct to said opening.

2. A furnace chamber within which combustion gases are generated and bounded in part by a wall including upright fluid cooled tubes, means for introducing low temperature heating gases into said furnace chamber to mix with the gases of combustion generated therein, said means including a duct extending transversely of and connected to said wall with said wall forming a common wall between said duct and said furnace, a group of consecutive tubes of said common wall having intermediate portions offset outwardly a substantial distance into said duct to provide an opening in said common wall and bent laterally in said duct relative to the centerline of said opening, with the intermediate tube portions near to the centerline of the opening being outwardly offset from the plane of said common wall a lesser distance than the remaining intermediate tube portions and with the intermediate tube portions on opposite sides of the centerline of said opening being bent laterally in opposite directions away from said centerline, means for substantially closing the intertube spaces of said intermediate tube portions so bent to form a shield for the protection of said duct from radiation from said furnace, said shield and com mon wall cooperating to define a passageway of decreasing vertical cross-sectional area in the direction of gas flow therethrough arranged to discharge low temperature gases from said duct to said opening.

3. A furnace chamber within which combustion gases are generated and bounded in part by a wall including upright fluid cooled tubes, means for introducing low temperature heating gases into said furnace chamber to mix with the gases of combustion generated therein, said means including a duct extending transversely of and connected to said wall with said wall forming a common wall between said duct and said furnace, a group of consecutive tubes of said common wall having intermediate portions offset outwardly a substantial distance into said duct to provide an opening in said common wall and bent laterally in said duct relative to the centerline of said opening, with the intermediate tube portions near to the centerline of the opening being outwardly offset from the plane of said common wall a lesser distance than the remaining intermediate tube portions and with the intermediate tube portions on opposite sides of the centerline of said opening being bent laterally in opposite directions away from said centerline, means for substantially closing the intertube spaces of said intermediate tube portions so bent to form a shield for the protection of said duct 7 from radiation from said furnace, said shield and common Wall cooperating to define a pair of passageways of decreasing vertical cross-sectional area in the direction of gas flow theretbrough disposed on opposite sides of and leading to said opening and arranged to discharge low temperature gases from said duct to said opening.

References Cited in the file of this patent UNITED STATES PATENTS Van Brunt et a1. May 20, 1941 Cermak Dec. 22, 1942 Allen Apr. 29, 1958 Koch Oct. 21, 1958 FOREIGN PATENTS France May 26, 1954 France Oct. 26, 1955

Images