DE3940381A1 - Duct for gas turbine exhaust gases - consists of outer and inner wall, insulating layer and cover plates and rails - Google Patents

Abstract

The duct for exhaust, gases has an outer (1) wall on the inside of which is a heat-insulating layer covered on the inside by an inner wall (3) itself consisting of juxtaposed plates spaced apart to allow for expansion. Elongated cover-sections (5) cover the expansion-gaps. The cover-sections have two superimposed cover-rails (6, 7) spaced apart on their lengthwise edges by the thickness of the inner wall-plates (4). The edges (4a) of inner wall-plates fit into the free intermediate spaces (11). Evenly spaced-out bolts (8) fixed to the outer wall go through the heat-insulating layer and have washers (9, 10) by which the cover-sections are secured against the inner wall plates. USE/ADVANTAGE - The heat-insulating layer is protected at high temperatures and gas-through-flow speeds by covering sections.

Description

The invention relates to a hot gas duct accordingly the preamble of claim 1 and a closure element according to the preamble of claim 12.

A hot gas duct according to the generic term of the Anspru ches 1 is for example by WO 88/09 458 knows. The cover elements are here by simple che, just trained, elongated rails det the expansion joints between adjacent interior cover wall panels.

Practical experience with such hot gas channels show, however, that the holder of the thermal insulation layer through the inner wall panels and the elongated ones Cover elements is insufficient. In this known Execution bulge only with thermal expansion overlapped sheets because of the attachment to the bolts free movement is often prevented. The hot gas (the a gas velocity in exhaust gas ducts of gas turbines up to 60 m / s) then backwashes the ble che and attacks the thermal insulation, which after a certain operating time from the wall of the hot gas duct is torn out.

Another disadvantage of the known embodiment is that the pressure on the thin cover plates forces only on the fastening bolts be recorded, which easily has the consequence that this Tear sheet metal, which is also the most reliable Bracket of the thermal insulation layer impaired.

The invention is therefore based on the object Hot gas duct according to the preamble of the claim ches 1 so that the inner wall panels in particular reliable due to the cover elements in their position are kept and in this way the thermal insulation layer even at high temperatures and high currents The speeds of the gas are properly protected is. Furthermore, it is an object of the invention, also a movable ver arranged in a hot gas duct Form the closing element so that the contained therein Thermal insulation layer is reliably protected.

This object is inventively characterized by nenden features of claims 1 and 12 solved. Expedient ßige embodiments of the invention are the subject of Subclaims.

In the hot gas duct according to the invention contain the Cover elements two covers arranged one above the other rails that ab in the area of their longitudinal edges Stand have about the thickness of the inner wall che corresponds. Into the two cover rails a cover element in the area of the two longitudinal edges Free spaces formed thereby attack the be neighboring inner wall panels with their edge.

This results in the area of the edges Inner wall panels through the two cover rails of the Ab cover element, the over or under these edges fen, a baffling multiple redirection for the Gas that is between the edge of the inner wall panel and the cover element surrounding this edge into the interior the channel wall tries to penetrate. In the course of this multiple, bully-like redirection becomes the stream  Mung energy of the hot gas so far that the Gas - if it is under the inner wall panels at all reaches - no damage in the channel wall can do things. This is especially the case at the beginning known execution occurring recycle the inner wall panels and pulling out the heat reliably avoided.

Some embodiments of the invention are in the Illustrated drawing. Show it

Fig. 1 (viewed from the inside of the channel ago) a plan view of a portion of a hot gas duct according to the invention,

Fig. 2, 3 and 4 show sections along lines IIII, III-II and IV-IV of Fig. 1,

Fig. 5 shows a variant (corresponding to the section shown in Fig. 2),

Fig. 6 is a sectional view (corresponding to Fig. 2) through the edge region,

Fig. 7 is a perspective view of a swivel flap arrangement according to the invention in a hot gas duct.

The hot gas duct schematically illustrated in FIGS . 1 to 4, in particular for exhaust gases from gas turbines, contains a stable outer wall 1 , on the inside of which a heat insulation layer 2 is applied.

The inside of the heat insulation layer 2 is covered by a wall 3 in contact with the hot gases, which is constructed as follows.

The inner wall 3 contains a plurality of Innenwandble Chen 4 , which are rectangular and are spaced a (see FIG. 1) to form expansion joints next to each other.

Furthermore belong to the inner wall 3 elongated cover elements 5 , which cover the expansion joints between the inner wall sheets 4 . These cover elements 5 contain two stacked cover rails 6 , 7 , which have a distance in the region of their longitudinal edges 6 a, 7 a, which speaks approximately to the thickness of the inner wall sheets 4 ent.

With the outer wall 1 bolts 8 are firmly connected (for example welded), which are arranged at regular intervals (see. Fig. 1) and penetrate the heat insulation layer 2 . They each carry two mounting plates ( 9 , 10 ) through which the cover elements 5 are fixed from below and above and - as will be explained in more detail - are held in contact with the inner wall plates 4 .

In the exemplary embodiment illustrated in FIGS . 1 to 4, the cover elements 5 each consist of two profiled cover rails 6 and 7 , which bear against one another in their central, flat cross-sectional area (see FIG. 2) and in their through the longitudinal edges 6 a, 7 a limited outer cross-sectional areas are profi le with formation of free spaces. The inner wall panels 4 engage in these free spaces with expansion play.

The cover rails 6 , 7 of the cover elements 5 are profiled such that the adjacent longitudinal edges 6 a, 7 a of the cover rails 6 , 7 of a cover element 5 point towards each other and between these cover rails 6 , 7 an inwardly widening inter mediate space 11th is present, the maximum height of which is a multiple of the thickness of the inner wall sheets 4 .

The inner wall sheets 4 are bent at their edge 4 a and engage with this bent edge 4 a in the inwardly widening space 11 of the cover rails 6 , 7 (see FIG. 2).

Between adjacent, parallel to each other and fixed by bolts 8 cover elements 5 are arranged in the transverse direction cover body 12 (see. Figs. 1 and 4), the elements formed in the region of their ends in the 5 of the cover rails 6 , 7 of the adjacent capping elements 5 free Intervene space 11 .

The transversely extending cover body 12 best hen from two flat cover rails 13 , 14 and egg nem spacer 15 arranged in between, the thickness of which speaks approximately to the thickness of the inner wall panels 4 ent.

The spacers 15 of the cover body 12 are bent at their ends 15 a and engage with these bent ends 15 a in the widening gap 11 of the cover rails 6 , 7 of the cover elements 5 .

In the non-deformed state, the two cover rails 6 , 7 of the cover elements 5 expediently have a distance in the region of their two longitudinal edges 6 a, 7 a which is somewhat smaller than the thickness of the inner wall sheets 4 . Then, when installing the hot gas duct, the inner wall panels 4 with their edges 4 a in the cover rails 7 are inserted and then the cover rails 6 are placed and fixed by means of the mounting plates 10 , so there is a slight elastic deformation of the cover rails 6 and 7 in their outer cross-sectional areas, so that the longitudinal edges 6 a, 7 a of the cover rails 6 and 7 with pressure on the Innenwandble Chen 4 rest. In this way, a particularly good seal between the cover rails 6 , 7 and the inner wall panels 4 is achieved, which largely precludes the penetration of gas from the hot gas channel into the heat insulation layer 2 .

The offset of the inner wall panels 4 on their engaging in the cover elements 5 edge 4 a ensures that the inner wall panels 4 can not slip out of the cover elements 5 even under extreme stresses, such as during operational pressure surges and with strongly pulsating pressure.

The cranking of the ends 15 a of the spacers 15 of the cover body 12 extending in the transverse direction serves the same purpose and ensures a reliable co-holding of the cover elements 5 and the cover body 12 running transversely thereto.

The cover elements 5 are divided into intervals (for example, a few meters). In the middle of their length, they are fi fi xed on a bolt 8 . In the remaining area of their length, they have elongated holes 16 (cf. FIG. 1) which are intended for holding the cover elements 5 on bolts 8 , but which permit thermal expansion of the cover elements 5 in the longitudinal direction relative to these bolts.

While the cover rails 6, 7 of the cover 5 approximately, for example in the example illustrated in FIGS. 1 to 4 exporting formed profiled, Fig. 5 shows a simplified variant in which the cover rails 6 ', 7' formed flat, whereby between these plane Cover rails 6 ', 7 ' a (with the cover rail 7 'connected) spacer 17 is provided, the thickness of which speaks about the thickness of the inner wall panels 4 ent. Also in this embodiment, this results from the engagement of the inner wall panels 4 in the cover elements 5 'a baffle-like deflection for the gas from the interior of the hot gas channel between the inner wall panels 4 and the cover rails 6 ', 7 'into the heat insulation layer 2 to ge long searches.

Numerous modifications are within the scope of the invention of the described embodiments possible.

For example, the cover rails 13 , 14 of the cover body 12 ( FIG. 3) can also be screwed (instead of welded) to the spacers 15 , a fixed point being expediently chosen in the central region of the length and elongated holes being provided in the usual round to provide an expansion game to enable.

Furthermore, the edges 4 a of the inner wall sheets 4 ( FIG. 2) and the ends 15 a of the spacers 15 ( FIG. 4) can also be bent upwards instead of downwards. Such an embodiment enables simplified assembly, which can largely be prepared in the factory.

In the embodiment illustrated in FIG. 1, additional bolts 8 'are provided in the middle of the fields formed by the inner wall panels 4 . However, these central fixed points of the inner wall sheets 4 are not required in all cases, but can be omitted in particular with smaller dimensions of the inner wall sheets 4 .

Fig. 6 illustrates an exemplary embodiment for the design of the cover 5 in the edge region. From the cover rails 6 , 7 are bent on one side by 90 ° and overlap with this bent loading area 6 b, 7 b, the free end face of the heat insulation layer 2 . The ends of the areas 6 b, 7 b can be bent again in order to grip the outer wall 1 behind.

Fig. 7 also shows an embodiment of a arranged in egg nem hot gas duct, movable closure element, namely a swivel flap assembly 20 , which includes two swivel flaps 21 , 22 , by means of drive devices 23 , 24 about axes 25 , 26 in the opening or opening Closed position can be pivoted. Here, the pivoting flap 21 in the opening position and the pivoting flap 22 is illustrated in the closed position. The common flap housing of both swing flaps is designated 27 . It is inserted as an intermediate piece in the hot gas channel (not illustrated).

The two swivel flaps 21 , 22 are constructed in the manner in which this was explained with reference to FIGS . 1 to 6 for the wall of the hot gas channel.

The swivel flaps thus contain a heat insulation layer, which is covered at least on one side by a wall 3 ', which consists of a plurality of spaced-apart wall plates 4 ' with the formation of expansion joints and from the expansion joints covering elongated cover elements 5 '' or transversely for this extending cover bodies 12 ''.

As in the case of the exemplary embodiment explained with reference to FIGS . 1 to 6, bolts 8 '' are also provided, which put the heat insulation layer at regular intervals through and carry mounting plates through which the cover elements 5 '' are in contact with the wall plates 4 ' will.

The cover elements 5 '' contain - as has already been explained with reference to FIGS. 1 to 6 - two stacked cover rails which have a distance in the region of their longitudinal edges, which corresponds approximately to the thickness of the wall plates 4 '.

In the free cover spaces formed by the two cover rails of a cover element 5 '' in the region of the two longitudinal edges, the adjacent wall plates surface 4 'engage with their edge. These edges are expediently bent (as already explained with reference to FIG. 2).

For the design of the transversely extending cover body 12 '' that already applies to Fig. 4 applies.

In the embodiment shown in Fig. 7, a stable support frame 28 is provided on the wall 3 'opposite side of the heat insulation, under which there is a sheet 29 , on which then follows the (not visible in the drawing) heat insulation layer.

However, it is also possible within the scope of the invention to provide the heat insulation layer 2 on both broad sides with egg ner wall 3 ', ie with the cover explained in detail with reference to FIGS. 1 to 6.

Claims (13)

1. containing hot gas duct, in particular for exhaust gases from gas turbines

• a) an outer wall ( 1 ),
• b) a heat insulation layer ( 2 ) lying against the inside of the outer wall ( 1 )
• c) an inner wall ( 3 ) covering the inside of the heat insulation layer ( 2 ), consisting of
  • c ₁ ) a multiplicity of inner wall plates ( 4 ) arranged next to one another with the formation of expansion joints,
  • c ₂ ) and elongated cover elements ( 5 , 5 ') which cover the expansion joints,
• d) with the outer wall ( 1 ) firmly connected, arranged at regular intervals bolts ( 8 ) which penetrate the heat insulation layer ( 2 ) and support washers ( 9 , 10 ) through which the cover elements ( 5 , 5 ') in plant the inner wall plates ( 4 ) are held,

characterized by the following features:

• e) the cover elements ( 5 , 5 ') contain two superimposed cover rails ( 6 , 7 and 6 ', 7 '), which have a distance in the region of their longitudinal edges (z. B. 6 a, 7 a) corresponds approximately to the thickness of the inner wall panels ( 4 );
• f) in the two cover rails ( 6 , 7 or 6 ', 7 ') of a cover element ( 5 or 5 ' ) in the loading area of the two longitudinal edges (z. B. 6a, 7a) ge free spaces ( 11 ) engage the adjacent inner wall panels ( 4 ) with their edge ( 4 a).

2. Hot gas duct according to claim 1, characterized in that the cover elements ( 5 ') from two flat cover rails ( 6 ', 7 ') and an intermediate angeord Neten spacer ( 17 ), the thickness of the spacer ( 17 ) approximately corresponds to the thickness of the inner wall panels ( 4 ). 3. Hot gas duct according to claim 1, characterized in that the cover elements ( 5 ) consist of two profiled th cover rails ( 6 , 7 ) which abut each other in their central, flat cross-sectional area and in their th through the Längskan ( 6 a, 7 a) limited outer cross-sectional areas to form the free spaces ( 11 ) intended for engagement of the inner wall sheets ( 4 ) are filleted. 4. Hot gas duct according to claim 3, characterized by the following features:

• a) the cover rails ( 6 , 7 ) of the cover elements ( 5 ) are profiled such that the adjacent longitudinal edges ( 6 a, 7 a) of the cover rails ( 6 , 7 ) of a cover element ( 5 ) in the direction of each other and between these cover rails ( 6 , 7 ) an inwardly widening inter mediate space ( 11 ) is present, the maximum height of which is a multiple of the thickness of the inner wall plate ( 4 );
• b) the inner wall panels ( 4 ) are bent at their edge ( 4 a) and engage with this bent edge in the inwardly widening inter mediate space ( 11 ) of the cover rails ( 6 , 7 ).

5. Hot gas duct according to claim 1, characterized in that between adjacent, parallel to each other and by bolts ( 8 ) fixed cover elements ( 5 ) extending transversely covering body by ( 12 ) are arranged in the region of their ends in the Cover rails ( 6 , 7 ) of the adjacent cover elements ( 5 ) formed free space ( 11 ) engage. 6. Hot gas duct according to claim 5, characterized in that the covering body in the transverse direction by ( 12 ) from two flat cover rails ( 13 , 14 ) and an intermediate spacer ( 15 ) be, the thickness of the spacer ( 15 ) approximately corresponds to the thickness of the inner wall panels ( 4 ). 7. Hot gas duct according to claims 4 and 6, characterized in that the spacers ( 15 ) from the cover body ( 12 ) are bent at their ends ( 15 a) and with these bent ends ( 15 a) in the widening space ( 11 ) of the cover rails ( 6 , 7 ) of the cover elements ( 5 ) engage. 8. hot gas duct according to claim 1, characterized in that the two cover rails ( 6 , 7 ) of an individual cover elements ( 5 ) in the non-deformed to stand in the region of their two longitudinal edges ( 6 a, 7 a) have a distance that is somewhat is smaller than the thickness of the inner wall sheets ( 4 ), so that in the space ( 11 ) between the cover rails ( 6 , 7 ) located inner wall sheets ( 4 ) the elastically shaped cover rails ( 6 , 7 ) with pressure on the inner wall sheets ( 4 ) lie on. 9. Hot gas duct according to claim 1, characterized in that the bolts ( 8 ) each with two mounting disks ( 9 , 10 ) are fixedly connected, between which the individual cover elements ( 5 ) are arranged. 10. Hot gas duct according to claim 1, characterized in that the spaced capping elements ( 5 ) are each fixed in the central region of their length on a bolt ( 8 ) and the rest of their length for holding the cover elements ( 5 ) further bolts ( 8 ) have certain elongated holes ( 16 ) which permit thermal expansion of the cover elements ( 5 ) in the longitudinal direction relative to these further bolts ( 8 ). 11. Hot gas duct according to claim 1, characterized in that the cover rails ( 6 , 7 ) of the cover elements arranged at the edge ( 5 ) are bent on one side by 90 ° and with this bent region ( 6 b, 7 b) the free Grip over the front of the heat insulation layer ( 2 ). 12. Movable closure element arranged in a hot gas duct, such as a louvre flap, swivel flap or slide flap, is characterized by the following features:

• a) The closure element contains a heat insulation layer, which is covered at least on one side by a wall ( 3 '), the Chen from a variety of spaced apart with the formation of expansion gaps arranged wall plates ( 4 ') and from the expansion joints covering elongated Cover elements ( 5 '') exist;
• b) there are the heat insulation layer at regular intervals penetrating bolts ( 8 '') vorgese hen carry the washers through which the cover elements ( 5 '') are held in contact with the wall sheets ( 4 ');
• c) the cover elements ( 5 '') contain two mutually arranged cover rails which have a distance in the region of their longitudinal edges, which corresponds approximately to the thickness of the wall plates ( 4 ');
• d) in the two cover rails from a cover element ( 5 '') in the region of the two longitudinal edges formed free spaces engage the adjacent wall plates ( 4 ') with their edge.