DE928248C - Large-capacity articulated boiler with medium-sized fuel shaft for hot water and steam generation for collective heating systems - Google Patents

Description

Large-capacity, articulated boiler finitely medium fuel filling shaft for Hot water and steam generation for collective heating systems The invention relates to a large-capacity articulated boiler with a central fuel filling shaft for hot water and steam generation for collective heating systems and consists in that the boiler sections towards the filling chute a heating surface connected upstream of the drawbar without a continuous one Train and an entry point on the large limb bulge at the level of the combustion chamber for the heating gases in .den first climb, the top in one over the dropping pull reaching the entire limb height passes.

This ensures that the tension channels despite the large link width do not have to be too wide, also that the entry tunnels for the heating gases in the first climb are as low as possible and that vertical traction surfaces with more extensive Dissolution in tube form, as previously usual, can be formed. According to the state of the technology are hot water and large steam boilers for collective heating systems that consist of Links are composed and have the above characteristics, not yet known.

The object of the invention is in the drawing in three figures shown as an exemplary embodiment.

Fig. I shows an elevation cross-section after the parting line of the boiler sections cut; Fig. A shows a horizontal cross-section through a boiler section dar; Fig. 3 shows an enlarged partial section of the boiler section along line i-a in ab-, b. i.

For the sake of simplicity, Fig. I only shows the boiler half with letters marked, the left half of the boiler is mirrored to this. All known details are in the representation of the boiler for the sake of clarity omitted, especially end links, fittings, pipe connections, etc.

According to Fig. R, the boiler body consists of the one behind the other Side members a, which are in the usual way in the water spaces with nipples one below the other are connected and form the filling shaft b between them. The climbing train entrance Side links is the low-lying entry point c, the drop-pull exit is with d denotes. The flue gas duct e after the fox and chimney is below of the boiler sections a arranged so as to achieve large Zugkanalheizflächen of the boiler sections nothing is lost on this heating surface due to the recess.

Except for the ascent pull f and your fall pull g is on the boiler section a according to the invention against the filling chute b to the: upstream of the draw channels Heating surface h arranged. This additional heating surface h is in contrast to the Heating surfaces of the ascending trains f and falling trains g are a train heating surface, but it becomes heated without a continuous draft from the combustion chamber, the one below Limb bulge i is formed. The lower part of this heating surface h is through direct radiation from the furnace, the upper part heated by the fact that the hot gases cooled in the upper part between the narrow, water-cooled walls in a permanent, inevitable exchange with the very hot gas in the lower part Part! 1 of this must come from the area enclosed by the heating surface. The heating surface h can; as well as the heating surfaces of the ascending trains f and the falling trains g through the Cleaning opening 1, cleaned well and easily through the cleaning opening k from above will.

The heating surface h of the side section a allows the entry point c for the riser to be placed as low as possible in order to achieve a long riser f, despite the large section bulge i for the combustion chamber: In addition, the widths of the risers f and dropping trains g do not need to be kept too large . Furthermore, this also results in the advantageous vertical tension channels, which allow the vertical pipe structure described below.

The total heating surfaces of the boiler sections a are below; like out Fig. R and the cross section of a boiler section in Fig. 2 can be seen, in a known manner, but more extensive than before, in tubular shapes with a circular cross-section, with intermediate webs. q and attached ribs dissolved. Due to this extensive dissolution in the form of a tube the boiler sections a are significant against the increased internal pressure with hot water heating more resistant than the previously common boiler sections of heating boilers. the Crosses na mean additional inner stiffeners on small ones :, flat ones Limbs ,.

Another new feature of the boiler sections a is that of the radiation from the furnace most exposed zone zi (fig. r) the links, vertical cut along the line r-2 in Fig. r to the boundary line, according to Fig. 3, a wider, oval cross-section running into the troughs o between the pipe cross-sections have p. As a result, the boiler sections are kept more elastic in zone n than staring into the firebox, which is less stressed by direct heat than tubular members, which is of great advantage for the resistance of the boiler members a is against the effects of fire.

The dissolution of the entire fire-irradiated or hot-gas contact The heating surfaces of the boiler sections are approx. Tubular in shape, with intermediate webs q still have ' the advantage that with the same external dimensioning of the boiler sections a, a much larger one and a better applied total heating surface of the boiler sections is achieved than with flat limb walls.

Claims (1)

PATENT CLAIMS: r. Large room = articulated boiler with a medium fuel filling shaft for hot water and steam generation for collective heating systems, characterized in that the boiler sections (a), facing the filling shaft (b) , have a heating surface (h) upstream of the draft ducts without a continuous draft and on the large section bulge (i ) have the entry point (c) for the heating gases in the first riser (f) at the level of the combustion chamber, which at the top turns into a drop (g) that extends over the entire link height. z .. Large-capacity sectional boiler according to claim z, characterized in that the boiler sections have a pipe-like structure, ie, cut horizontally, circular cross-section with intermediate webs (q), which in the zone (s) most exposed to radiation from the combustion chamber turns into an oval , in the troughs (o) between the pipe cross-sections expanding cross-section (p) merges.