DE2264354A1 - HOLLOW BODY FOR HEATED GASES - Google Patents

Description

Hollow body for heated gases The invention relates to a hollow body for heated gases under overpressure, which hollow body has a rotationally symmetrical one Outer wall and one in the hollow body running essentially parallel to the outer wall, having perforated partition, the space between the outer wall and the partition wall is filled with heat-insulating materials.

Such hollow bodies are used as pressure vessels or, in particular, as pipelines, e.g. in a circuit of a gas turbine plant with a gas-cooled nuclear power reactor used: With the known hollow bodies of this type such as the Swiss patent specification 242 910 shows the perforation of the partition delimiting the space because of the pressure equalization between the space and the rest of the space of the hollow body intended. As a result, the heat-insulating materials are not only in the space thermal loads, which, for example, result in the so-called creep of the substances can have, but also in cases of pressure changes in the heated gas exposed to mechanical loads. There are, for example, sudden high changes in pressure up to 10 at / sec and more possible.

In addition to the loads just mentioned, acoustic and other loads also have an effect Vibrations in the pipelines mechanically affect the insulation layer.

As a result of the thermal as well as the mechanical stress on the insulation layer can in the previous hollow bodies in the space between the outer wall and The partition wall creates empty spaces in the insulation layer, creating the insulation layer could be gradually destroyed until the hollow body due to excessive thermal Load on its outer wall would have to be taken out of service.

The inventor set himself the task of creating a hollow body for under To create excess pressure heated gases, which, compared with the previous Hollow bodies, a longer service life and a higher level of operational reliability.

In the case of the hollow bodies described at the beginning, this is achieved in that in the space between the outer wall and the perforated partition wall one or several perforated ones running essentially parallel to the outer wall and the partition wall Partitions are provided which divide the space into two or more layer spaces divided or subdivide, and that the throttling effect of the perforated partition and with respect to the perforated partition (s) of the hollow body increases from inside to outside from wall to wall.

It is advantageous if the perforated partition or the perforated Partitions made of an alloyed, heat-resistant sheet steel is or are.

The perforated partition and the perforated partition or the perforated partition walls to increase the resistance to bending of the walls are provided with annular bead profiles running in the direction of rotation of the wall.

For using the hollow body according to the invention for the pipeline it is advantageous if the perforated partition is inside with respect to the hollow body a front wall substantially parallel to the partition wall is upstream, with between a distribution space is left free for the partition wall and the front wall, and the front wall in the direction of the gas flow has a ring of openings only in places.

Another advantage is achieved in that to hold the partition or the partition walls, the partition wall and the front wall support rings are provided, which from the outer wall to the front wall essentially radially to the hollow body run, whereby the layer spaces and the distribution space in the direction of the gas flow are divided into axial sections, and further by being the pretext Only a single ring of openings over the length of each axial section shows, the respective plane of the ring of the openings perpendicular to the longitudinal axis of the hollow body and in the vicinity, however, in the direction of the gas flow before the the respective axial section of the distribution space is delimiting the carrier ring.

On the basis of the attached schematic drawings of exemplary embodiments of the invention, the subject matter of the invention is described and explained in more detail below.

1 shows a hollow body according to the invention, namely a Pressure vessel with part of a pipe connecting to the pressure vessel, Fig. 2 shows another hollow body, namely a pipeline.

The hollow body designed as a pressure vessel has a rotationally symmetrical one Outer wall 1 on. In the hollow body there is one which runs parallel to the outer wall 1 perforated partition 2. Between the outer wall 1 and the perforated partition 2, an interspace 4 is left free, which is filled with heat-insulating materials is and protects the outer wall 1 from the direct effects of the heated, in the hollow body introduced gas. In the space 4 between the outer wall 1 and the perforated partition 2 is one to the outer wall 1 and the partition 2 substantially parallel perforated partition 3 is provided and subdivided so the space 4 in two layered spaces filled with insulation materials. the Throttling effect of the perforated partition 2 and the perforated intermediate wall 3 increases from the partition 2 to the partition 5, i.e. it increases with respect to the hollow body from inside to outside from wall to wall. This is the mechanical load the thermally more heavily loaded partition 2 is lower than the mechanical load the thermally less stressed partition 3. This also means that the thermally higher loaded layer space between the partition wall 2 and the Partition wall 3 less mechanically stressed than the thermally less stressed layer space between the outer wall t and the intermediate wall 3.

The perforated partition 3 has a smaller number of the same size Perforation holes 10 as the perforated partition wall 2. This is the throttling effect the partition 3 is larger than that of the partition 2. The greater throttling effect the partition 3 could also be reached in another way, e.g. by having the same number but of smaller perforation holes 10 than it is in the partition wall 2. It must that is, the total cross-section of the perforation holes 10 from the partition 2 to the partition 3 be smaller.

The partition 2 and the partition 3 are made of alloyed heat-resistant Steel sheets executed.

To increase their resistance to deflection, the partition wall is perforated 2 and the perforated partition 3, each running in the direction of rotation of the walls Annular bead profiles 9 provided. It would also be conceivable to have walls 2 and 3, for example, with a Square, triangular or half-ring profile having ribs to be provided.

On the pressure vessel> in the picture on the right, one closes Pipeline. The construction of a pipeline according to the invention is described below described.

As is particularly shown in Fig. 2, the hollow body of the pipeline a rotationally symmetrical outer wall 1 and one in the hollow body perforated partition 2. The one left free between the two walls i and 2 Gap is by means of two to the outer wall 1 and to the partition wall 2 essentially parallel perforated partition walls) 'and 3 "in three tiered rooms 4 ', 4 "and 4"' divided. The partition 2, as well as the two partition walls 3 ', 3 "are with annular bead profiles running in the direction of rotation of the walls 2 or 3 'or 3" 9 provided to increase the resistance to deflection of these walls.

The partition 2 is preceded by a front wall 5. She lies regarding of the hollow body on the inside of the partition 2 and runs essentially parallel to it. A distribution space 6 is left free between the partition 2 and the front wall 5. the Front wall 5 is in the direction of the gas flow, which is indicated in the drawing by means of the arrow is illustrated, provided only in places with a wreath of openings 7, which lead from the distribution space 6 into the inner space of the hollow body. This Space is limited by the front wall 5 and intended for guiding the gas flow.

-In the hollow body are to hold the partition walls) 'and 3 ", the partition 2 and the front wall 5 carrier rings 8 are provided.

They run from the outer wall 1 to the front wall 5 essentially radially to the hollow body and are connected to these walls 1 and 5. Subdivide this the carrier rings 8, the layer spaces 4 ', 4 "and 4"' as well as the distribution space 6 in Direction of gas flow in axial sections. To hold the partition 2 and the Partitions 5 'and) ", the carrier rings 8 are provided with brackets, in which the walls 2, 3 'and 5' 'are mounted with an axial play. The shift rooms 4 '> 4tt and 4 "' are filled with insulation material.

The front wall 5 has the length of each axial section of the distribution space 6 each has only one ring of openings 7. The plane of the wreath of openings 7 runs perpendicular to the longitudinal axis of the hollow body and lies in the vicinity, but in the direction of the gas flow in front of the carrier ring 8, which the each axial section of the distribution space 6 is limited.

To compensate for longitudinal expansion, the front wall 5 is single on each axial Section of the distribution space 6 divided into axial parts by means of a gap 11. The gap 11 is covered by a sleeve 12.

It would be conceivable that the space 4 between the perforated partition 2 and the outer wall 1 with even more spaces 5 than was shown to be provided in order to subdivide the space into several layers. The layer spaces could be much thinner, as well as those for the partition walls 5 sheets to be used.

Claims (6)

Claims Hollow body for heated gases under excess pressure, which hollow body one rotationally symmetrical outer wall and one essentially parallel in the hollow body to the outer wall running, perforated partition wall, wherein the intermediate space between the outer wall and the partition wall filled with heat-insulating materials is that in the space (4) between the outer wall (1) and the perforated partition (2) one or more to the outer wall (1) and perforated partition walls running essentially parallel to the partition wall (2) (5) are provided which divide the intermediate space (4) into two or more layer spaces (4 ', 4' ', 4 "') divided or subdivide, and that the throttling effect of the perforated Partition wall (2) and the perforated partition (3) or the perforated partition walls (3 ', ") increases with respect to the hollow body from inside to outside from wall to wall. 2. Hollow body according to claim 1, d a d u r c h g e k e n nz e i c h n e t that the perforated partition (3) or the perforated partition walls (3 ', 3 ") is made of an alloyed, heat-resistant steel sheet or are. 3. Hollow body according to claim 1, d a d u r c h g e k e n nz e i c h n e t that the perforated partition (2) and the perforated partition (3), or the perforated partition walls (3 ', 3 ") to increase the resistance to deflection the The walls are provided with annular bead profiles (9) running in the circumferential direction of the walls are. 4. Hollow body according to claim 1 for a pipeline, d a d u r c h it is not noted that the perforated partition (2) with respect to the hollow body a front wall (5), which is essentially parallel to the partition wall (2), is positioned in front of the inside, a distribution space (6) being left free between the partition (2) and the front wall (5) is, and the front wall (5) in the direction of the gas flow only in places a wreath of openings (7). 5. Hollow body according to claim 4, d a d u r c h g e k e n nz e i c h n e t that for holding the partition (3) or the partition (3 ', ″) of the partition (2) and the front wall (5) support rings (8) are provided, which from the outer wall (1) to the front wall (5) run essentially radially to the hollow body, whereby the stratified spaces (4 ', 4 ", 4"') and the distribution space (6) in the direction of the gas flow are divided into axial sections. 6. Hollow body according to claim 5, d a d u r c h g e k e n nz e i c h n e t that the front wall (5) over the length of each axial section respectively only has a single ring of openings (7), the respective level of the ring of the openings (7) runs perpendicular to the longitudinal axis of the hollow body and in the vicinity, however, in the direction of the gas flow in front of the respective axial portion of the distribution space delimiting carrier ring (8) is located.