DE6928814U - SELF SUPPORTING STEAM GENERATOR - Google Patents

Description

Great

Waagner-Biro Aktiengesellschaft in Vienna $

"Self-supporting steam generator"

The invention relates to a self-supporting steam generator with congruent boiler cross sections, in particular a two-drum steam boiler in modular construction.

The invention is characterized in that all steam generators of a series have essentially the same overall height and length, that is to say the same boiler cross-sections, and the width of the steam generator, in particular their boiler drum length is proportional to their steam generation. According to another invention The characteristic is the length of the superheater tubes and, if applicable, the number of tubes connected in series proportional to the required steam overheating. In the case of the two-drum steam generator, the upper drum and approximately are attached to it Parts of the steam generator on the central pipes of the Evaporator tube bundle arranged, which the load of the drum feed onto the lower drum or into the foundation. The inner tubes of the evaporator tube bundle are preferably included a larger diameter and possibly with a larger wall thickness arranged as the rows of outer evaporator tubes.

The invention is shown schematically and by way of example in FIGS. 1 to 5.

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Figure 1 shows a cross section through the two-drum boiler, Figure 2 shows the arrangement of the evaporator pipes and the stiffening partition, Figure 3 shows the construction of the stiffening wall, Figure k shows a detail of the drum support on the evaporator pipes, Figure 5 shows the suspension of the superheater and preheater pipes.

According to the invention, the boiler cross section shown in FIG. 1 remains with boilers of different power levels always the same. The boiler output is increased by extending the boiler drum, i.e. the boiler gets wider. The entire boiler consists of completely identical components placed side by side, with only the Boiler drum 12 and the lower drum 13 have a different length. Each component contains everything needed to create it and superheating of the steam or for heating the tube bundle is necessary. Such a component has a width, for example of about 180 cm and contains two oil burners in the combustion chamber 1 16 and the associated heating surfaces 2 to 6. One part the evaporator tubes 5 are combined to form steering walls 8 and 9, which guide the flue gas flow through the steam boiler in an approximately meandering manner. The flue gas flow generally takes place here in the longitudinal direction of the pipes. Cross flows, i.e. flue gas flows in the direction of the boiler width or the boiler drum 12 do not take place. Be near the boiler outlet the flue gases combined and optionally an air preheater 19 forwarded. The exhaust gases then flow from this in a manner known per se.

This construction has the advantage that relatively little construction work has to be done in the technical office because

essentially all the same pipe coils are used. Only the superheater has to be adapted to the required conditions these coils are essentially corrected only lengthwise. Another advantage of this design is that the flow conditions on the flue gas side are independent of the nominal output of the boiler.

With this construction it is essential that all pipes of the heating surfaces 2 to 6 are the same in width of the boiler are large, with individual rows of tubes in this transverse division being able to be omitted if necessary. The basic division is like this for example 75 mm. It is at the same time for all fin walls, which finally the steering wall 8, the front wall 7 and the

! Form side walls, decisive. The double division, so for

Example 150 mm is then for the division of the superheater heating surfaces 2 to 4 or also for the rear wall 10 determining. Bulkheads are then, for example, with 300 mm pitch or with 600 mm Division carried out (in each case a multiple of the basic division). This law has the advantage that when passing through one heating surface through the other, for example from pipes of the superheater 2 to 4 through the steering wall 8 and radiation protection wall 26, difficulties never arise and, above all, no transverse bends are required.

The entire boiler is designed to be self-supporting, only the lower drum 13 and the front wall 7 are by suitable Constructions supported. So is the lower drum 13 and thus Most of the heating surfaces of the boiler on a support 18 and the front wall 7 on the support 17-

The main direction of flow of the flue gases is always vertical

upwards or vertically downwards. The smoke gases flow like this,

apart from the deflections, always parallel to the Rochr axes. This results in less contamination of the heating surfaces during boiler operation.

Just as all pipes within the longitudinal section have the same bending profile over the entire width of the boiler, also has
the right and left side walls always have exactly the same shape for all boiler sizes.

To clean the steam from entrained moisture, cyclones (not shown) are provided as built-in drums. By this design is due to the larger diameter of the upper drum 12 compared to the lower drum 13. For the same reason will too the preheating of the feed water in the economiser is not up to the saturated steam temperature operated because this water is used as motive water for the injectors.

The superheater and preheater heating surfaces can be easily pulled out towards the top. So there is no need for separate hanging tubes =

The stiffening of the radiation protection wall 26 and the steering wall 8
takes place jointly through the zigzag stiffening tubes 21, which are designed as evaporator tubes. These stiffening tubes are each welded once on the radiation protection wall 26 and once on the steering wall 8 with webs and thus together result in a framework of high rigidity. The boiler itself is called
Overpressure boiler operated. For this purpose, the boiler walls are designed as gas-tight membrane walls.

The number of pipes through which there is parallel flow on the steam side, in particular of the superheater, is made by changing the number of tubes of the individual meander adapted to the design data. For example, if there are forty pipes, 5 meanders with 8

Pipes or 8 meanders with 5 pipes or k meanders with 10 pipes,

etc. can be chosen. The passage grids on the guide walls 8 and 9 are formed by omitting the fins at these points. The steering wall 8 is arranged between the individual superheater packages, the radiant superheater 2, the semi-radiant superheater 3 and the contact superheater k . The two outer rows of tubes of the evaporator bundle 5 are designed as guide walls 9, that is, they are fin walls, the fins being left out only at the smoke gas passage points.

The steam boiler is heated by the burners 16, which are arranged in the burner air boxes 15. The fuel is burned in the combustion chamber 1. The flue gas flows via the radiant superheater 2, the semi- radiant superheater 3, the contact superheater k, the evaporator 5 »into the economiser 6, and finally via the exit of the flue gases from the boiler near the floor into the air preheater 19 14 between the floor and the lower combustion chamber limitation, which is formed by the tubes, which at the same time result in the front wall of the boiler, to the burner air boxes 15 and finally to the burners 16. Here, too, a level flow is sought for the combustion air, so that the branching problems do not exist for the individual burners.

In Figure 2, a boiler part, in particular its evaporator tubes, is shown schematically in section. The evaporator tubes are clamped between the boiler drum 12 and the lower drum 13 in the two-drum boiler. The boiler drum 12 is here carried by the reinforced boiler tubes 23 arranged in the middle of the tube bundle. The boiling tubes 23 are useful? · wise to shorten their buckling length with the other boiling tubes

5 connected by webs 2k . A part of the boiler pipes forms the partition wall 8 along which the flue gas is guided.

In the case of the radiant superheater 2, which in most cases serves as the final superheater, the hot end part of the superheater is in front To protect the large irradiation of the combustion chamber 1, a radiation protection wall 26 is arranged. This wall has for example a pipe division of 150 mm and is designed as an evaporator like the evaporator tubes 5 · The Superheater bulkheads, whereby direct radiation into the second superheater half is avoided. Of course you can this superheater stage also consist of two parts, with the separate end superheater behind the radiation protection wall come to lie.

At the same time, this radiation protection wall 26 is reinforced by stiffening pipes 21 connected to the steering wall 8. This construction is shown in FIG. You can see here that these stiffening pipes 21 designed as boiler tubes and arranged in the manner of half-timbered diagonals. They branch off the pipes the radiation protection wall 26 and open separately into the upper drum 12th

In Figure k , the connection of the evaporator tubes 13 and 23 to the boiler drum 12 is shown in detail. According to this construction, the evaporator tubes 5 and 23 are connected to one another by webs 24 at certain intervals.

In Figure 5, the suspension of the preheater heating coils 6 and the superheater heating coils 2 to k is shown schematically. These heating coils 2 to k and 6 hang on yokes 27, which are again supported on the boiler drum 12. This construct

tion is based on the observation that, in general, the weight of the preheater pipes approximately equal to the weight of the Superheater tubes

Claims (1)

Expectations 1 . Self-supporting steam generator, particularly two-drum steam boiler, characterized in congruent boiler sections and steering walls in modular construction, all the steam generator of a series of substantially the same height, that the heating surface tubes are (2 to 7) are arranged in all boiler sections approximately equal and the steering walls of one side wall up to the opposite one, whereby the heating medium is always guided in the plane of the boiler cross-section, and that the width of the steam generator and thus the length of the boiler drum is proportional to the nominal amount of steam of the boiler and the length of the steam generator, i.e. the distance from the front wall ( 7) from the rear wall (1O) is essentially the same for all boilers of the series. 2. Steam generator according to claim 1, characterized in that that the length of the superheater tubes (2, 3) and preferably the number of superheating tubes connected in series is approximately is proportional to the required superheating of the steam. 3 · Steam generator according to claim 1, characterized in that that in a two-drum steam boiler, the upper drum (12) and any parts of the steam generator attached to it on the central Pipes (23) of the evaporator tube bundle are arranged, which introduce the load of the drum (12) onto the lower drum (13) or into the foundation (18). k. Steam generator according to claim 3i, characterized in that the innermost row of the evaporator tube bundle (5) has evaporator tubes (23) of larger diameter and in particular greater wall thickness than the rows of outer evaporator tubes. ι »st »1 I. I * 1 5. Steam generator according to claim k, characterized in that the evaporator pipe (5) are connected at one or more points of their length by webs (2 ^). 6. Steam generator after. Claim k, characterized in that the outer rows of the evaporator tubes (5) form guide walls (9) for the flue gases. 7 · Steam generator according to claim 6, characterized in that that between these steering walls (9) on one side of the Keseel- / drum drum superheater packages (k) and on the other side of the Kesael preheater heating surfaces (6) are arranged. 8. Steam generator according to claim 7 »characterized in that that the superheater and preheater heating surfaces (k, 6) ^{are attached to yokes r} (27), which are supported on the upper boiler drum (12). 9. Steam generator according to claim 6, characterized in that that in front of the first steering wall (8) on the hot side of the boiler § drum a radiation protection wall (26) for the final superheater (3) J is arranged $, which is led by a series of evaporator tubes «Is formed. 10. Steam generator according to claim 9 »characterized in that that from the radiation protection wall (26) diagonally extending pipes (21) branch off in the manner of half-timbered diagonals, which are ; steaming medium are flowed through. j 11. Steam generator according to protection claim 10, characterized by draws that the diagonal boiler pipes (21), which ι branch off from the radiation ^{protection wall (26 1} ), also with the behind the steering wall (8) are connected urtd together form a rigid framework system. 0928814