DE2945877A1 - Internally insulated hot gas duct for fast flows - has insulation cover plates fixed by sleeved bolts to duct wall - Google Patents

Abstract

Thermally insulated gas duct of large dimensions is intended for conducting high temp gas at high speed and comprises a support structure on the cold (outer)side, cover plates on the hot(inner) side and insulation between these outer and inner sides. The hot cover plates are connected to the cold support structure by through bolts passing completely through the insulation; each bolt has a spacer sleeve bearing against the inner face of the outer (cold) duct and terminating at the other end at a short distance from the bolt head to form an annular gap between underside of bolt head and end of spacer sleeve. The hot side cover plates fit into this annular gap. Used for hot gas ducts in high temp reactor systems, process plants and breeder reactors. By using a spacer sleeve, the pull of the bolt clamping the inner cover plates in position is transmitted directly onto the spacer sleeve and through it to the outer support duct, without relying upon comprssion of the insulating material. Thus the inner cover plates are firmly anchored against flutter due to the high speed gas flow without depending upon the resilience and resistance of the insulation.

Description

Thermally insulated gas duct

large size The present invention relates to a thermal insulated gas duct of large dimensions, which with high flow velocity of a high temperature gas is flowed through, with a support structure on the cold Side and cover plates for the insulating material on the hot side, which means the entire insulation penetrating retaining bolts are attached to the support structure while slightly compressing the insulating material.

Such gas channels are used as gas routing components in Systems with closed gas circuits such as high-temperature reactors and process heating systems or in fast breeders, the gas ducts being preferred as coaxial gas supply systems are trained. Such a gas routing system is described, for example, in the laid-open specification 24 39 224.

In the known gas supply system, the hot gas lines are all provided with an inner insulation, which is a multi-layer fiber or metal foil insulation executed and attached in shots to the pressure jacket or support tube. The inner one Gas guiding jacket is suspended elastically from the support tube in shots. To with a result of a Rapid pressure changes occurring in the event of an accident result in an excessively high mechanical load To avoid thermal insulation, insulation with perforated sheets is recommended covered. With such an open thermal insulation "there is There is a risk of forced convection, which would destroy the insulating effect can. From the above-mentioned published patent application as well as from the published patent application 22 57 699 it is known that forced convection is formed by foreclosure of the individual sections from which the gas ducts are composed, too prevent. The isolation takes place by means of forced convection barriers in the form of Double cones on the one hand on the support tube and on the other hand on the gas guide jacket are welded on.

In the known gas channels, the double cones are used at the same time Fastening and centering of the gas duct jacket.

This type of attachment is also used in one in the laid-open specification 27 05 314 shown thermal insulation applied. This isolation is the space between the pressure jacket or support tube and the gas guide jacket a multitude of thin-walled sealing elements divided into individual chambers. In each chamber several layers of radiation sheets are arranged, which by means of Spacers and hollow bolts welded to the gas guide jacket are fixed.

The space between the radiation plates can be filled with fiber mats be.

Thermal insulation for areas exposed to a hot gas flow is guided along is known from laid-open specification 26 43 284. At this for reactor pressure vessels or Gas pipes usable insulation the gas guide jacket formed by perforated cover plates is fastened by means of bolts held, which is welded both to the pressure jacket or liner and to the cover plates are. The insulating material applied in several layers to the pressure jacket or liner is slightly compressed by the cover plates.

The state of the art is further thermal insulation for Reactor pressure vessel, which has several layers of highly porous metallic mesh and thin sheets of metal disposed between the layers. Every layer of the mesh consists of several metal mesh layers, one of which is perpendicular to the layer plane Wave structure is embossed. The insulation is covered by retaining plates and slightly compressed. The retaining plates are guided through the entire insulation Bolt connected to the liner of the pressure vessel, the bolt connected to the liner welded and screw connections are provided on the hot side. Such a one Isolation is described in laid-open specification 21 59 781.

The fastening of the cover or retaining plates to the pressure jacket by means of bolts or liner has the purpose of "fluttering" the cover or retaining plates through the To prevent flow excitation. At the same time, as already mentioned, the Cover or retaining plates exerted pressure on the insulating material, so that in this the required preload is generated. However, this has a disadvantageous effect that the position of the cover or retaining plates depends on the restoring forces of the insulating material is dependent.

Based on the aforementioned prior art, there is therefore the The invention is based on the object of a thermally insulated gas duct of large dimensions specify the type described above, regardless of the elasticity of the insulating material a vibration-proof mounting of the insulating material protecting Coverage is achieved.

According to the invention, this object is achieved in that on each A spacer sleeve is pushed onto the retaining bolt, one end of which is attached to it the support structure that supports at the other end of each spacer sleeve between it and the head of the retaining bolt is provided with an annular gap and that the cover plates are fixedly mounted in these annular gaps.

The positive connection of the cover plates with the retaining bolts The cover plates can be fixed using spacer sleeves without affecting the spring rate the insulating material can influence the position of the cover plates. So that will the uncertainty about the course of the spring constants at high temperatures and switched off over a long period of time, which leads to the operational safety a thermal insulation designed according to the invention is increased.

The insulating material can consist of ceramic fibers, metallic foils or metallic fabric. The creation of the prestress in the insulating material is possible in the main or shunted force.

The insulating material can consist of one layer or several layers on top of one another. In the latter case, each layer is that is formed for example by a fiber mat, at the holes for the retaining bolts provided with a border. The borders also act as convection barriers.

The spacer sleeves are advantageously divided into as many sections how layers of insulating material are present; the individual sections can then - for example, using sheets attached to the surrounds - as spacers serve for the bezels.

The cover plates can be rectangular, arched in a manner known per se or just be designed. It is advantageous to insert some of the retaining bolts into the To arrange centers of these rectangular cover plates; these bolts only have the task of preventing the cover plates from fluttering.

The remaining retaining bolts are expediently provided at the points where four of the rectangular cover plates collide. These retaining bolts are used at the same time, the cover plates are in the correct position in relation to one another to keep. In order to do justice to this further task, each of these retaining bolts between the spacer sleeve and the head of the retaining bolt, which is enlarged in this case a spacer disc can be arranged, which rests with a collar on the bolt head. There are four of the cover plates between the spacer and the bolt head stationary stored.

About the emergence of stresses as a result of thermal expansion of the cover plates to avoid, can be arranged between the four cover plates arranged around a retaining bolt and the collar of the spacer should be left a gap.

Both the retaining bolts located centrally in the cover plates as the "corner" retaining bolts can also be screwed into the supporting structure.

The retaining bolts also do not need to be attached directly to the supporting structure but they can be screwed into panels attached to the Support structure are attached.

The drawing shows several exemplary embodiments of the invention Excerpts from thermally insulated gas ducts are shown schematically. The figures show in detail: FIG. 1 a piece from a first thermally insulated gas duct with a retaining bolt arranged in the center of a cover plate (hereinafter fixed bolt called) in longitudinal section; Figure 2 a piece from the same gas duct with a Corner bolts; FIG. 3 shows a section from a second thermally insulated gas duct with a fixed bolt, also in longitudinal section; Figure 4 shows a detail of a third thermally insulated gas duct with a fixed or corner bolt.

Figures 1 and 2 show a piece of a hot gas duct, for example in a nuclear reactor plant that from the core of a high-temperature reactor exiting cooling gas heated up to temperatures of 1000 0C to a heat exchanger or a gas turbine engine.

The hot gas guide consists of a support structure 1, which is inside with thermal insulation is provided. The inner insulation comprises the insulating material 2 and a plurality of cover plates 3, the insulating material 2 on its inside Protect from the hot cooling gas. Ceramic fibers and metallic fibers can be used as insulating material Foils or metallic fabric layers can be used.

The cover plates 3 are flat and square in this embodiment executed. They are held in their position by means of corner bolts 4 (FIG. 2), whereby the corner bolts 4 are each provided at the points where four cover plates 3 (of which two plates 3a and 3b are shown) butt against each other. At the center of everyone Cover plate 3 is another bolt 5, called a fixed bolt, arranged without play (Fig. 1). The fixed bolts 5 are primarily used to fix the cover plates 3, unambiguous, defined relbpaths and thus bending stresses on the corner bolts 4 to generate.

By means of the corner bolts 4 and the fixed bolts 5, all of which are in the supporting structure 1 are screwed in, a pressure is applied to the insulating material via the cover plates 3 2 exercised and generated in this the required bias. The corner bolts 4 and the fixed bolts 5 are provided with heads 6 and 7, respectively, with which they are attached to the cover plates Press 3.

To the position of the cover plates 3 from the restoring forces of the insulating material To make 2 independent, spacer sleeves 8 are pushed onto bolts 4 and 5, which are supported at one end on the supporting structure 1. At the other end of the spacer sleeves 8 is in each case a space between the sleeves and the bolt heads 6 and 7 released. In the case of the fixed bolts 5, an annular gap 9 has thus arisen, and a cover plate 3 is fixedly mounted in each of these annular gaps 9, as shown in FIG Fig. 1 can be seen.

With the corner bolts 4 is in each case in the free space between the spacer sleeves 8 and the bolt heads 6 a spacer 11 is arranged which has a collar 12. With this collar, the spacers 11 are on the bolt heads 6, so that an annular gap 10 between the disc body and the associated bolt head 6 is formed. This fact can be seen in FIG. 2. In the ring gaps 10 each four cover plates 3 are fixedly mounted, with between the four Cover plates 3 and the respective collar 12 a gap 13 is left open to the Not to hinder thermal expansion of the cover plates 3. The heads 6 of the corner bolts 4 are enlarged compared to the heads 7 of the fixed bolts 5 and close with the spacers 11.

In Fig. 3 is a section from another hot gas duct shown that differ from that just described in the nature of the insulating material differs. It is only part of the hot gas duct with a fixed bolt shown; the corner bolts can be designed in the same way as in FIG Fig. 2.

The insulating material 14 consists of several layers lying on top of one another 15, which are each formed by a mat in the case of fiber materials. Each layer 15 has a border 17 at the bores 16 for the fixed bolts 5 as the end of the mat on. The surrounds 17 simultaneously act as convection barriers and prevent thus a gas flow through the insulation.

On each fixed bolt 5 a spacer sleeve 18 is pushed, which of a plurality of sections or rings 18a is formed.

The number of rings 18a corresponds to the number of layers 15 of the insulating material 14. By means of plates 19 attached to the surrounds 17, which between the individual Sections or rings 18a are plugged in, the bezels 17 are in the correct Kept their distance.

The holes provided in the insulating material 14 for the corner bolts can be bordered in the same way as the holes 16 for the fixed bolts.

FIG. 4 shows a detail of a hot gas duct in which the retaining bolts (Fixed bolt 5 or corner bolt 4) not directly connected to the supporting structure 1, but are passed through these and screwed into plates 20, which means Screw connections 21 are attached to the support structure 1.

Claims (8)

Claims thermally insulated gas duct of large dimensions, which flows through with a high flow rate of a gas of high temperature with a support structure on the cold side and cover plates for the insulating material on the hot side, the retaining bolts that penetrate the entire insulation are attached to the supporting structure and slightly compress the insulating material, characterized in that on each retaining bolt (4, 5) a spacer sleeve (8; 18) is pushed on, one end of which is supported on the supporting structure (1), that at the other end of each spacer sleeve (8:18) between it and the head (6, 7) of the retaining bolt (4, 5) an annular gap (9, 10) is provided and that the cover plates (3) are fixedly mounted in these annular gaps (9, 10). 2. Thermally insulated gas duct according to claim 1, characterized in that that the insulating material (14) consists of several superimposed layers (15) and that each layer (15) has an enclosure at the bores (18) for the retaining bolts (5) (17). 3. Thermally insulated gas duct according to claim 2, characterized in that that the spacer sleeves (18) are divided into as many sections (18a) as layers (15) of the insulating material (14) are present, the individual sections (18a) serve as spacers for the mounts (17). 4. Thermally insulated gas duct according to claim 1 or 2, characterized in that that part of the retaining bolts (5) in the centers of the rectangular, curved or flat formed cover plates (3) is arranged. 5. Thermally insulated gas duct according to claim 1 or 2, characterized in that that a part of the retaining bolt (4) is provided at the points where four are rectangular formed cover plates (3a, 3b) abut one another, with each of these retaining bolts (4) between the spacer sleeve (8) and the head (6) of the enlarged in this case Retaining bolt (4) a spacer (11) is arranged, which with a collar (12) on the bolt head (6) and that between the spacers (11) and #en associated bolt heads (6) each four cover plates (3a, 3b) mounted stationary are. 6. Thermally insulated gas duct according to claim 5, characterized in that that in each case between the four cover plates arranged around a retaining bolt (4) (3a, 3b) and the collar (12) of the spacer (11) a gap (13) is left free. 7. Thermally insulated gas duct according to claims 4 and 5, characterized characterized in that the retaining bolts (4, 5) are screwed into the supporting structure (1) are. 8. Thermally insulated gas duct according to claims 4 and 5, characterized characterized in that the retaining bolts (4, 5) are attached to the supporting structure (1) Plates (20) are screwed in.