US2654352A - Steam generator support and casing structure of box column construction - Google Patents

Description

N m mm m FT m m 0 m CU .C MX .0 DB F O Oct. 6, 1953 STEAM GENERATOR SUPPORT AND CASING STRUCTURE Filed Feb. 28, 1952 9 Sheets-Sheet l 3nnentor n; David M.Schoenfeld Oct. 6, 1953 D. M. SCHOENFELD STEAM GENERATOR SUPPORT AND CASING STRUCTURE OF BOX COLUMN CONSTRUCTION 9 Sheets-Sheet 2 Filed Feb. 28, 1952 0 O Q Q a U o O o a 0 Och 1953 D. M. SCHOENFELD ,654,

STEAM GENERATOR SUPPORT AND CASING STRUCTURE OF BOX COLUMN CONSTRUCTION Filed Feb. 28, 1952 9 Sheets-Sheet 3 O o a I Snnentor a R N David M. Schoenfeld D. M. SCHOENFELD STEAM GENERATOR SUPPORT AND CASING STRUCTURE Oct. 6, 1953 OF BOX COLUMN CONSTRUCTION 9 Sheets-Sheet 4 Filed Feb. 28, 1952 TVA Srwentor David M. Schoenfeld D. M. S CHOENFELD STEAM GENERATOR SUPPORT AND CASING STRUCTURE Oct. 6, 1953 OF BOX COLUMN CONSTRUCTION 9 Sheets-Sheet 5 Filed Feb. 28, 1952 D. M. SCHOENFELD STEAM GENERATOR SUPPORT AND CASING STRUCTURE Oct. 6, 1953 OF BOX COLUMN CONSTRUCTION 9 Sheets-Sheet 6 Filed Feb. 28, 1952 Oct. 6, 1953 D M. SCHOENFELD 2,654,352

STEAM GENERATUR SUPPORT AND CASING STRUCTURE OF BOX COLUMN CONSTRUCTION I Filed Feb. 28, 1952 9 Sheets-Sheet 7 24 9 8 7 J 2 Snventor David M. Schoenfeld Oct. 6, 1953 Filed Feb. 28, 1952 Fig. l2.

D. M. SCHOENFELD STEAM GENERATOR SUPPORT AND CASING STRUCTURE OF BOX COLUMN CONSTRUCTION 9 Sheets-Sheet 8 3nentor 4 David M. Schoenfeld (Ittomeg Oct. 6, 1953 D. M. SCHOENFELD STEAM GENERATOR SUPPORT AND CASI NG STRUCTURE OF BOX COLUMN CONSTRUCTION Filed Feb. 28, 1952 9 Sheets-Sheet 9 QJ T M re wm n 6 e D 0 m 3 S M M v 0 .D

(I meg Patented Oct. 6, 1953 STEAM GENERATOR SUPPORT AND CASING STRUCTURE OF BOX COLUMN CONSTRUC- TION David M. Schoenfeld, Scarsdale, N. Y., assignor to Combustion Engineering, Inc., New York, N. Y., a corporation of Delaware Application February 28, 1952, Serial No. 274,001

1 Claim.

This invention relates to steam generators of the boiler furnace type and it has special reference to supporting means for steam generators that are intended for marine service and that have spaced-apart inner and outer casings which form air chambers or air passages surrounding the generator heat absorbing elements and through which passages the air for combustion flows and is heated, by keeping the inner casing cool, before entering the boiler furnace with the fuel; the air passages also serving to prevent gases from the boiler and furnace from reaching the space outside thereof in the ship.

Recent requirements for a certain type of marine steam generator fitted in a ship call for the generator supports to resist vertical and/ or horizontal shock forces equivalent to at least about six times the weight of the generator. Furthermore, the requirements call for the total weight of the generator and casing to be a practical minimum; also for the casing to withstand a comparatively high air pressure within its inner portion as well as between its inner and outer portions.

Broadly stated, the object of this invention is to provide a novel design of support and casing for a marine steam generator which Will meet the requirements mentioned above.

A more specific object is to provide a boiler supporting and casing structure which is exceptionally strong and which has a minimum Weight.

Additional objects and advantages will become apparent as the disclosure and description hereof proceeds.

To achieve the foregoing, the supporting structure and casing have been designed to act as an integral unit in the form of two concentric box columns. Each of the corner columns, itself a smaller box column, unites adjacent sides of the inner and outer casings. Horizontal girders and trusses close the top of the casing structure (exclusive of the flue gas outlet opening) and the foundation structure closes the bottom. The inner and outer casings are fitted into the resulting frame structure. Horizontal trusses at suitable levels distribute the shock loads between the inner and outer casings. The column verticals withstand the bending action due to the athwartship and fore and aft shock loads, as Well as the vertical shock loads. The casing panels transmit the athwartship and fore and aft shock loads by shear to the boiler base, and also provide the strength required to withstand the shutoff pressure of the blower which furnishes the air for combustion of the fuel fired in the furnace .of the boiler. This construction provides a path for the shock loading on each item in the boiler from its position in the boiler to the four column footings, where the shock loads are applied to the boiler from the ship framing structure.

The invention itself will best be understood from the following description of an illustrative embodiment thereof when taken inconjunction with the accompanying drawings, wherein:

Figure 1 is a front vertical elevation, taken on line ll of Fig. 2, of a frame structure for a steam generator embodying one form of the invention; the casing panels being removed to more clearly show the structure.

Figure 2 is a plan view of Fig. 1 (also taken on line 22 of Fig. 8) showing the structure of the steam generator casing with the drum removed.

Figures 3, 4 and 5 are respectively the left, right and rear side vertical elevations of the structure of the steam generator, taken respectively on lines 3-3 and 44 of Fig. 1 and on line 55 of Fig. 2.

Figure 6 is a vertical cross section, taken on line 6- 5 of Figs. 1, 7, 8 and 9 showing the structure of the left side columns supporting the steam and water separating drum of the steam generator; this being the same as the outside structure of the left corner columns of the inner and outer casing walls.

' Figure '7 is a vertical cross section, taken on line 1-1 of Fig. 2, showing the front side structure of the front inner casing and rear side of the front drum columns.

Figure 8 is a vertical cross sectional elevation,

' taken on line 88 of Fig. 2, showing the heating elements including those of the economizer, of the steam generator and of the sup-erheater within the casing and the side walls and floor of furnace, and the Water circulation pump and its pipe connections to the steam generator for maintaining a controlled circulation of the boiler water.

Figure 9 is a vertical cross section, taken on line 99 of Fig. 2, showing the inner side structure of the rear inner casing and drum columns.

Figure 10 is a vertical cross section, taken on line IEE0 of Figs. 1, 2, 7, 8 and 9, showing the inside structure of the left side casing columns adjacent the drum supporting columns; these columns forming the corners of the inner and outer casing walls.

Figure 11 is a vertical cross section, taken on line I l-H of Figs. 2 and 8, showing the heating elements including those of the economizer, of the steam generator and rear wall of furnace and of the superheater within the casing and their respective headers and showing the means for supporting and sealing said headers into box structures which in turn are supported by the casing structures.

Figure 12 is a fragmentary portion of Fig. 11 to an enlarged scale showing typical structural details for supporting said headers and typical structural details for mounting the casing pan' els on the casing structure; 7

Figure 13 is a vertical cross-section;takenon line I3-I3 of Figs. 1, 2 and 8, showing the inner structure of the right side casing columns which form the corners of the inner and outer casing walls.

Figure 14 is a horizontal cross section, taken on line I i--54 of Figs. 1, 8 and1 1-, showingtyp ical horizontal beams within the casing. for stiffening the inner and outer casing walls and ri idly tying together the corner columns.

Figur 15 is a vertical cross section of a fra ment of Fig. 8 (atthe bottom of left casing wall 25) to an enlarged scale showing the mounting for the main supply header which distributes boiler water from the circulation pump to the steam generator elements;

In general the supporting structure and casing' for the steam generator elements are designed to act as a unit. The casing is in the form of two concentric boxes providing air chambers therebetween, atthe vertical corners of which boxes are vertically extending box columns. The sides of these columns which lie-between the inner and outer casing walls are preferably of lattice construction except where occasional plates are required for accommodating fastenings to other members of the structure'. Their outersides are imperforate plates wherever the column forms a'- part of the air tight casing. Corner columns and casings are unified through the employment of horizontally extending girders.

Figure 1 shows the front outercasing supporting structure with the casing panels (which provide access to the a-ir'chambers) removed. This front outer support structure comprises the left and right vertical corner columns respectively shown at I' and 2 together with horizontally extending and vertically spaced apart stiffeners 3, c 5 and here shown as structural steel channels, which arerigidly fastened to the outer faces of columns I and 2 by known means. The stiffeners 4, 5 and 6 extend to the left beyond colunir. I and over the Width of column Ia which mainly supports about half of the load of the steam and water drum 8. Said stiffeners are rigidly fastened to column Ia. Columns I and Id therefore are in eiTect a single column.

Said stiffeners 3, 4 and 5 have plates 9, f and I I respectively fastened on their inner sides which plates extend beyond the top and bot tom of stiffeners 4 and and the bottom of stiffener 3 to for-in ledges as shown, against which ledges the removable casing panels are fastened as by studs and nuts I2. Typical pan ls will be described at a later point herein. A vertical member I3 extendsbetween stiffener-s 3 and 4, and 4 and 5; is fastened to each; and divides the two openings. between stiffeners and columns I and 2 into four openings as shown. The panel-holding bolts I2 are placed around each of these openings and are fastened to the columns I and 2 as well as to the plates 9, I 0 and II.

Column 2 has an imperforate plate 011 its front side extending for the full width and height to serve as part of the air tight casing later to be described. The front face of column I a is of lattice construction for lightness as shown by Figs. 1 and 7, and may be made up: of angle irons or may be made" of a perforate plate shown in Fig. 3. A further stiffener I4 extends horizontally across columns I and Id (see Fig. 1) and is fastened to each. Plates I-5;- I6, I='I- and I8 (again see Fig. 1) are fastened to the rear sides of stiffeners 4, 5, I4 and 6 respectively where they cross column I, and extend beyond the top and/or bottom of said stiffener's'a's'shown, to form ledges against which the removable casing panels providing access to the air chamber are fastened as by bolts I2; typical panels being described below. Drum 3 is mounted in saddle I9 (see Figs. 1, 2, 3, 5, 6, 7', '9') which is fastened thereto and to the top of columns I and la.

Between columns I and 2 and stiffeners '5 and 6' are mounted removable panel structures 2002, their location being shown in dashed and dotted lines in Fig. 1 and shown in cross section in Fig. I-l. The outer panels 20a adjacent the burners 2| provide access to these burners. Said burn e'r's 2| (see Figs. 1, 7, 8) are mounted on the inside casing 22 (See also Fig. 11) and having suitable openings to establish communication between the space defined by'the inner and outer casings and the interior of the inner casing for the passage of heated combustion supporting air from said space into the interior of the inner casing; and the central fuel pipes of these burners 21 extend through said adjacent casing' panel's 20a. The outer panels 20a, surrounding" the space occupied by the burners, are mounted as by bolts I2, onto the lower ledge II of stiffener 5 (see Fig. 1), the upper ledge I of stilfene'r 3 (see also Fig. 1) and the front faces ofeolu-mns I and 2.

Figure 2 is a. plan view of the Fig. 1 boiler with the 8 shown in dashed and dotted lines (in order to achieve greater clarity in representing the boiler parts beneath the drum). From 2 it will be" seen that the four col- I', 2, 23 and 23 constitute the four corners for the outer and inner casing walls of the steam generator. The reference numbers for the outer casing walls are 26 for" the front wall, 25 for the left side wall, 26 for the rear wall, and 2! for the right side wall. The equivalent or corresponding inside walls are 28', 29, 30 and 3| (see again Fig. 2); said inner walls 29 and 3I being onset vertically as shown in Fig. 8.

The air spaces between left walls 25 and 29 and between right walls 21 and M are open at the top (Fig. 8); while the air spaces between front walls 20 and 28 and between rear Walls 26 and 30' are closed at the top by plates 32, 33 respectively (see Fig. 11). Moreover, the tops of columns 2 and 24 (shown at right of Figs. 1-2) are open at the top, While the tops of columns I, la, 23 and 23a (shown at left of Figs. l-Z) are closed by the plates 32a, 33a respectively (again see Figs. 1'-2'). It also will be noted that the saddles I9, I9 (see Figs. 1, 3. etc.) supporting the drum 8, fasten to and are supported by bracket members 49 (Figs. 10, 3 and 2) extending from the tops of columns Ia and 23a and further fasten to vertical members 34 extending upwardly on the right side of columns I and walls 29, 3| and 21 respectively, and that onto these walls the respective casing walls 38, 39 and 40 of an economizer 5! are fastened and supported (Fig. 8). The left economizer wall 38a rests upon and fastens to seal plate 35a (Figs. 2 and 8). The top flange ofoutside front wall stiffener 3 (Fig. 8) and the top of outside rear wall 26, fasten to and support the respective casing wall panels 42, 43 of economizer d! (Fig. 11) and inside walls 28 and 39 fasten to and support the economizer casing walls 44, 45, respectively. The economizer is principally supported by the casing walls 44, 45 through which the return bends 48 of the economizers tubular elements 4? project (see Fig. 11)

Figure 3 shows the left side of columns la and 23a to be of lattice construction for lightness. They are tied together at the top by channel 48. Bracket members 49, behind channel 48, support the saddles l9 and their superimposed drum 8 (see also Fig. 10). Imperforate plates 50, 5!, 33a and 52 extend from the left side to the right side of column 230; (at right angles to the plane of the paper in Figs. 3 and 6) to form an air intake conduit leading into the air spaces of the casing; said air intake conduit being shown in Fig. 14 (at upper left portion thereof). Said plates connect .to the walls 25, 26 (Fig. 14) and to the plate 53 on the left face of column 23 (Fig. 6). The former structure for supporting the removable casing panels will be described in the reference to Fig. 6.

Figure 4 shows the supporting structure of the right side outer casing wall of the steam generator. plates on their outer sides which serve as part of the outer air tight casing wall 2? (Figs. 2 and 8). As in Fig. 1, the casing panels which provide access to the air chamber between the inner and outer walls are removed (to clarify representation) and the casing supporting structure comprises horizontally extending and vertically spaced apart stifieners 5 1, 55, 56, 51, 58 and 59, here shown as structural steel channels, which are rigidly fastened to the outer faces of columns a 2 and 24. The stiffeners have plates 6E3, 5!, 62, 53, 64, 65 respectively fastened on their inner sides which plates extend beyond the top and/or bottom of the stiffeners to form ledges as shown,

against which the removable casing panels of the outside right wall 27 (Fig. 8) are fastened as by bolts 66.

Vertical members 6'! extend between the stiffeners where shown and are fastened thereto and divide each of all but one of the openings between the stifleners and columns 2 and 24 into two openings as shown. The panel-holding bolts F6 are placed around each of these openings and are fastened to the columns 2 and 24 as Well as to said plates and vertical member 5?.

Figure 5 shows the sup-porting structure of the rear outer casing of the steam generator. 001- umn 24 has an imperforate plate on its outer ide which serves as part of the outer air tight casing wall 26 (Fig. 1.1). Column 23a is of lattice construction for lightness on its lower portion and has an imperforate plate 53 on the upper portion forming a side of the air intake conduit (see Fig. 14) leading into the air spaces of the casing. As in Figs. 1 and 4, the casing panels which provide access to the air chamber space are removed and the casing supporting structure comprises horizontally extending and vertically spaced apart stifieners 68, 69, 10, H, 12, 1'3 here Columns 2 and 24 have imperforate 6 shown as structural steel angle irons (68, 13) and channels (69, 10, H, 12)

The channels are rigidly fastened to the outer faces of the columns 24, 23 and 23a and the angle irons are fastened to columns 24 and 23 with their outer faces flush. The columns 23, 23a thus are in effect a single column. The stifieners 69, 10, H, l2 have plates 14, I5, 76, T! fastened on their inner sides, which plates extend beyond the top and bottom of the stiffeners to form ledges as shown; and against these ledges the removable casing panels of the outside rear wall 26 (Fig. 11) are fastened as by bolts l8. Said plates 14, 75, lo, 77 extend across the width of column 23 as shown. Vertical members 19 extend between the stiffeners where shown and are fastened thereto and divide the openings between the stiffeners and columns 24 and 23 into a multiplicity of openings as shown. Four access openings are provided in column 23 as shown. Bolts 18 extend around each of these openings and are fastened to the columns 23 and 24 as well as to said plates and vertical members 19.

Figure 6 shows the left faces of columns I and 23, or the right faces of columns la and 23a, these being common to both columns, and supporting structure of the left side outer casing of the steam generator. 7

In this view the portions of the adjoining columns Ia and 23a other than the intermediate common face shown between columns la and I, and between 23a and 23, have been omitted from the drawing. Such omitted portions are the structural members of the front and rear faces of columns in and-23a, which members are at right angles to and frame into said common faces of columns I and la shown.

From Fig. 6 it will be seen that column I has an imperforate plate on its outer side which serves as part of the outer air tight casing wall 25 (Figs. 2 and 8). Column 25 has an imperforate plate 53 on the lower portion of its outer side which serves as part of the air tight casing wall 25. It is of lattice construction for lightness on the upper portion which lies within the air intake conduit (see Fig. 14) bounded by the imperforate plates 5i), 5!, 33a, 52 previously referred to in the description of Fig. 3. As in Figs.

'1, e and 5, the casing panels which provide access to the air chamber are removed from Fig. 6 (to clarify representation), except for the lowermost one which Fig. 6 does show.

The casing supporting structure represented in Fig. 6 comprises horizontally extending and vertically spaced apart stiffeners 80, 8|, 82, 83,

'84; shown as structural steel members, which are rigidly fastened to the sides of columns I and 23. stiffening member 83 comprises a plate provided with bracers 83a. The aforesaid stiffeners have plates 85, 88, 81, 88, 89 '(see also Fig. 8) respectively fastened to their inner sides which plates extend beyond the top and/or bottom of the stiffeners to form ledges as shown,

against which the removable casing panels of the outside left wall 25 (Fig. 8) are fastened. Vertical members 98 extend between the stiffeners where shown and are fastened thereto and divide each of the upper three openings between stiffeners and columns I and 23 into two openings as shown. Bolts 9! for holding the casing panels in place are provided around each of these openings and are fastened to the columns i and 23 as well as to said panel and vertical members 90.

The lowermost casing panel shown at 92 in Fig. 6 (see also Figs. 8 and 15) serves as a support for the header 93 from which boiler water is delivered to the various steam generating elements; the novel organization of these parts 92 and 93 being disclosed and claimed by co-pending application Serial No. 273,984 filed February 28, 19 52 in the name of Edward W. Ludt for Header Integral With and Sealed Into Boiler Casingjf As shown in Figs. 6 and 15 hereof, the header 93 is welded into the panel plate 92 thereby serving as a stiffening member for said plate and providing a communication between the outside water delivery pipe 94 to said header and the discharge pipes 95, 96 located within the air space of the casing. Stufiing boxes as otherwise required are thereby avoided.

In Figs. '3, 9, l and 13 omission has been made (as in Fig. 6 and also for purpose of clarifying representation) of the portions of the adjoining columns such as the structural members of the faces which are at right angles to and frame into the backs of the columns represented by those drawing views.

Figure 7 shows the front elevation of inside lower casing wall 22 which supports the burners 2| and shows the upper casing wall 28 thereabove (see also Fig. 11). It further shows the inner sides of box columns I, Ia and 2 to be of lattice construction for lightness.

Figure 9 shows the inside elevation of the inside casing wall 36 and the front sides of the box columns 23, 23a. and 24 to be of lattice construction for lightness. The upper portion of column 23a has an imperforate plate I which forms one side of the air intake conduit shown in Figs. 3, 5 and 6.

Figure 10 shows the inside elevation of the inside casing wall 29 (Figs. 2 and 8) and the right sides of the box columns I and 23. The column sides are of lattice construction for lightness except where plates are required for accommodating fastenings such as the structural members supporting the various headers of the steam generating tubes to be described below.

Figure 13 shows the inside elevation of the lower portion of the inside casing SI (see'Figs. 2 and 8) and the upper portion of the outside casing 21. It shows the left sides of the box columns 2 and 24 to be of lattice construction for lightness except where plates 9'! and 98 on columns 25 and 2 respectively are placed to support structural members 99 and I0!) supporting a steam generator header IOI to be described later.

Figure 14 shows a typical horizontal group of beams me, its, um, its located within the air spaces of the casing for stiffening the casing walls and rigidly tying together the corner columns I, 2, 24 and 23 to which they are fastened. The beams may be made with web plates of perforated steel sheets as shown in beams I02, I04

or the beams may be made latticed beams for lightness, as shown in beams I83, I85. There are a multiplicity of similar horizontal groups of stiffening beams located Within the air spaces of the casing at other vertical locations than the one group shown at section It in Figs. 8 and 11, that is made up of beams I02, I03, I04 and I85. Such groups of beams may occur at other levels such as I06, IU'F, I08 shown in Figs. 8 and 11 and in Figs."7, 9, l0 and 13; and a typical fastening of said beams to the casings is shown in Fig. 8

'xvhere beam It! is fastened to the inner stiffener Slb and to the outer casing stiffener 58.

Figures 8 and 11 show in general the locations of the economizer, steam generator and superheater elements within the casing. The products of combustion produced by the burning of fuel entering via burners 2| rise from the furnace I27 to pass upwardly across said elements to generate and heat steam.

The economizer M (Fig. 11) comprises a bank of horizontally disposed parallel spaced apart tubes 41 interconnected by return bends at as shown for serial flow of feed water therethrough from the inlet header I89 to the outlet header H9. The headers Hi9, H8 lie between the rear side economizer casing walls 43, 45; and outlet header I I8 is connected by a pipe (not shown) to the steam and Water drum 8. Preferably an air intake 48a (Figs. 8 and 11) is provided in the casing Wall 40 of the economizer; said air intake 4% being in supplement to the earlier mentioned first air intake for the boiler furnace, which first intake is shown at 52 in Fig. 14.

The secondary evaporator shown by Figs. 8 and 11 is made in two superimposed sections III and I I 2. Each section comprises a bank of horizontally disposed parallel spaced apart tubes II3 interconnected by return bends I I 4 for serial flow of boiler water from inlet headers I I5, I IE, to outlet header Ill. The headers H5, H8, II! lie between the rear side generator casing walls 26, 30.

The superheater shown by Figs. 8 and 11 at I I 8 comprises a bank of horizontally disposed parallel spaced apart tubes H9 interconnected by return bends I25 for serial flow of steam therethrough from the inlet header I2I to the outlet header I22.

The primary evaporator shown at I23 com prises a bank of horizontally disposed parallel spaced apart tubes I24 interconnected by return bends I25. One end of each of said tubes I24 connects into the outlet'header 26, as shown and the other end bends downwardly to continue along the side of the rear inside wall 38 facing the furnace I27, thence to pass through wall 30 to enter the inlet header I28 adjacent the bottom I29 of the furnace.

In Figure 8 are shown the evaporator tubes I39 linng the left, bottom and right walls respectively 29, I29 and BI of the furnace I27.

These tubes are parallel spaced tubes connected at one end to the inlet header I32 Within the air space between the left side walls 25, 28 of the casing and connected at the other end to the outlet header IllI within the air space between the right side walls 3 I, 27.

The economizer tubes 4? (Fig. 11) pass through the rear and front side easing walls 35, M respectively, and are supported thereby. The secondary evaporator tubes I13 are supported by members I34 passing vertically between tubes through the bank, which members are in turn supported by the relief or riser tubes I35 (see also Fig. 8). The superheater tubes I I9 are supported by members I38 passing vertically between tubes through the bank, which members are in turn supported by the relief or riser tubes It'll. The primary evaporator tubes I 24 are supported at one end by outlet header E26 and at the other end by pads under the return bends I25 which in turn rest upon'upper ledges of the inner front Wall 22 as shown.

The wall tubes I39 (Fig. 8) are supported from the headers I32, Isl and by the furnace bottom I29. The riser tubes I35, I31 (Fig. 8) through which the steam and water mixture from the outlet header IilI passes to the drum 8, are supported by said header at the right end and by 9 said drum at the left end. The loads'of the evaporator banks of tubes I I I, I I2 plus the superheater bank of tubes II8 are transmitted by the relief or riser tubes I35, I31 to the drum 8 and the header IOI of the wall tubes I30.

The principal supports of the header IIlI as mentioned above are structural members 98, 99 (Figs. 13 and 12) which are framed into the columns 2 and 24. Brackets I38 are fastened as by welding, onto the ends of header IOI and rest upon the members 98, 99. The remaining headers I32 (Fig. 8) and H5, H6, III, I2I, I22 and I26 (Fig. 11) are supported in similar manner to that typically shown in Fig. 12 for headers H6, I2I, I22. Each header in Fig. 12, has angle members I39 fastened longitudinally thereto adjacent its inner side from end to end as by welding. Each header H and I22 has angle members I44 fastened thereto adjacent its outer side, the two angles I45 being fastened together to form a gas tight seal therebetween. The angles I39 each fasten to a plate I4I extending outwardly from the inside casing wall 3!] toward the headers.

The inside wall plates I42 are fastened to plates I4I as by welding to form a gas tight seal therewith. Both plates I4I and I42 and the angles I39, I48 extend for the full width of the wall 34 to the adjacent columns 23 and 24 to which they are fastened. End plates I43 adjacent the columns 23, 24, close each end of the gas tight chamber formed by the headers I I5, I22, the associated angles I39, I44 and plates I4I, I42 to which they are fastened, as by welding. Similar end plates I44 close the chamber formed by header IZI, the associated angles I390; and plates I4Ia, I42a. The end plates I43, I44 are each provided with holes I45 through which bolts pass to fasten them to the vertical members of columns 24 as shown. The fastenings of the end plates I43, I44 adjacent column 23 to said column 23 are similar to those shown and described with relation to column 24.

From the above description it will be seen tha all of the elements of the steam generating unit comprising the economizer, the evaporator sections including those on the furnace walls, the superheater, all of the associated headers and the steam and water separating drum are all ultimately supported by the corner columns represented at I--Ia, 2, 24 and 2323a in Fig. 2 and other views.

The attachment of the removable casing panels to the outside walls is typically shown in Fig. 12. Typical panels I45 of rear outside wall 26 comprise plates I4? backed by insulation I48. Each plate I 4! is strengthened by hat or bracer sections in the form of members (not shown) attached to the outer surface of the plate (in the way that members 83a of Fig. 6 are attached to plate 83), along which surface they extend vertically in spaced relationship. The plates I47 extend over the ledges formed by plates I4, I5 which extend beyond the stiifeners 69, II! respectively (see also Fig. 5). Studs I8 are fastened to said ledges and pass through holes in the yokes I44. By means of nuts on said studs I8 bearing against battens I49 as shown, which in turn bear against plates I 41 (while heeling against plates I4, the plates I41 are snugly held against the ledge plates I4, I5. Gaskets (not shown) are provided between plates I41 and I4, I5 to make gas tight joints. A similar construction is used to fasten all of the removable casing panels of all the outside casing walls to the outer wall casing frame structures. The weight of all of said casing panels is thereby carried through said frame structure to the corner columns.

The inside casing walls 28, 29, 35, 3i are divided into flanged panels 28a, 25a, 35a, 3Ia, as typically shown in Figs. 8 and 11. These may be removable and are generally supported by horizontal structural members such as channels 28b, 29b, 30b, 3Ib which in turn extend to and are fastened to and are supported by the corner columns I, 2, 23, 24.

Controlled circulation (sometimes referred to as forced circulation) of boiler water through the steam generating elements is accomplished by a pump shown at I54 in Fig. 8 and driven by a motor .or turbine I5I. A pipe I52 is connected to the drum 8 and to the pump inlet for supplying of boiler water, and a pipe 94 connects the pump discharge to the distribution header 93 to the inlet header I32 of wall tubes I30 and delivers water thereto. The relief or riser connections I35, I31 between outlet header IIII of Wall tubes I30 to the drum 3 have already been described at an earlier point herein. A water supply pipe 96 connects the distribution header 93 (Fig. 8) to the inlet header IIE of the evaporator section H2 and a pipe I53 interconnects the pipe 95 and the inlet header II5 of the evaporator section I I I.

The secondary evaporator sections I I2, I I I discharge steam and water via the extension I54 of outlet header III directly into drum 8. Pipes I55 adjacent the left side and rear furnace walls (Fig. 8) connect into pipes 95 and into the inlet header I28 of the primary evaporator I23 for water supply thereto. A pipe I56 connects the outlet header I26 of the primary evaporator I25 to the drum 8 for steam and water discharge therethrough. The usual steam supply connection from the drum 8 to the superheater inlet header I2I (Figs. 8 and 11) is external of the casing and not shown, but the weight of this connection is supported by the drum and header which in turn carry said weight to the drum and easing columns.

From the foregoing it has been seen that the complete steam generator casing provides a novel supporting structure for all the elements of the steam generating unit. The illustrative casing and support structure here disclosed is capable of resisting vertical and horizontal shock forces equivalent to at least about six times the weight of the generator; the casing and generator unit are of minimum weight in construction; and the casing comprises two spaced apart inner and outer casing Walls (the inner casing itself being gas tight) forming a fluid tight compartment therebetween on the sides of the unit, vertical box columns of lattice construction at the corners of said compartment, and horizontally extending, vertically spaced stiffening beams and girders between columns and casing and fastened thereto.

While one preferred embodiment of invention has been here shown and described, it will be understood that such disclosure is illustrative rather than restrictive and that changes in construction, combination, and arrangement of parts may be made without departing from the spirit and scope of the invention as claimed.

What I claim is:

A boiler for marine use comprising an upright structural steel frame having four upright latticed columns of rectangular transverse section ri r'fiin the earners of the name; hori'z'ontalli disposed lattice'd beamsinte'rconnecting adja cent columns at vertically spaced intervals, the inner and outer extremities of the beams: corre spending with those ofthe columns; metallic panel's disposed-adjacentthe inner extremities ofthe' beams and columns and secured tosaid beams" and columns so as to form a fluid tight mner casing for the boiler; means forming abot tom for the interior of the inner casing;- steam generating tubes lining-the inner surface of said bottom and the lower portion of the inner casing; metallic panels disposedadja'cent the outer-extreiriities of the beams and columns and held in fluid tight engagement therewith by removable clamps secured to said beams and engageable with said panels; a steam'and water drum sup ported hy twobf said columns and-secured to said outer panels in a fluid tight-manner so thata; portion of the drum wall-forms a portion of the outer casing with the remainder of a said outer casing beingmade up of'said outerpanels; meansfs'ealing the top and'b'ott'o'm of the space embraced by said inner and outer oasirigsyone of said 'c'olumns'having anopening forthe entrance of air; fuel burning means adjacentthe lower portion of the frame for introducing 'fu'el into-the interior of the inner casing; saidburning-"nie'a'ns having openings for the passage of air from the space between the casings into the interiorof the inner casing; economizer, steam generating and superheating serpentine tube sections-vertically spaced in the upper portion of the inner casings; headersfor-e'ach-ofsaid tube sections and for the steam generating tub 's in the lower portion of the casing, saidheaders being positionedwithin the-Space between the inner and outer casing and adjacent the place Where'the tubes of the associated tube section passes through the inner wall to connect to said headers; angled members extending throughout the length of said-headers and welded thereto 'and to an adjacent part of said columns thereby s'u'pporting.safid hfidersfromsaid latter'columnsis tirely 'within saids'paeeand connecting said dis-1 tributin'g header with the inlet headers "ofthe steam generating tubes; and fluid conveying tubs'eiitendingentirely'within said space and interconnecting the outlet headers of the economizer and the'steam' generating tubes and the inlet header of superheater tubes with the steam and water'drfi'm.

DAVID'M. SCI-IOENFELD.

References Cited in the file of thispatent UNITED STATES PATENTS Number Name Date 1,733,169 Purdy Oct. 29, 1929 1,318,418 Millard Aug. '11, 1%31 1,394,692 Kerr et al. Jan. 17, 1933 1,958,124 'Bernis 1 f' May 8, 12,34 1,988,338 Mioton "Jan. 15,1935 2,011,423 Sheldon -1. Aug. '13, 1935 2,105,500 Parsons Jan. 18, ,'1938 2,134,000 Mayo Oct; '25, 1933 2,175,933 Walsh Oct. .10, 1939 2,209,580 Sargent -4 July '30, 1940 2,355,800 Hensel Aug.,15, I944 2,499,478 Feser -1." Mar. 7, 1950 2,529,643 'Borton Nov. 14,- 1950

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