DE1052750B - Wall of a combustion chamber for liquid fuel, especially in gas turbines - Google Patents

Description

GERMAN

The invention relates to a combustion chamber for liquid fuels, in particular in gas turbines with an inner wall surrounding the combustion chamber, which at least in part consists of a Large number of mutually spaced flat sections with straight narrow edges formed scope exists, with each section separately by only a limited heat transfer from the interior to the outside allowing support elements held on an outer support device is.

Combustion chambers with such inner walls are known per se. In these known combustion chambers the individual sections are not exclusively spaced apart by air gaps that are attached to each other connect the circumference of the sections. In a known combustion chamber, the sections are located in mutual contact via edges and are held in their position by intermediate ribs. These intermediate ribs lie between the rows of the individual sections.

In another known combustion chamber, radiation plates are provided through which air flows.

The invention is now based on the object. a construction to indicate the destruction of the Wall prevents excessive overheating.

According to the invention this object is achieved in that the distances between the individual sections are formed by air gaps directly adjoining the circumference of the sections and the sections on the side facing the interior are in alignment with one another and form an uninterrupted surface from mosaic elements. (For the partial feature of the formation of an unsettled surface of mosaic elements through the side of the mutually aligned sections facing the interior Independent protection is not claimed.)

The solution according to the invention is distinguished from the previously known ones by its simplicity. It there are no spacers or strips between the individual pieces forming the inner wall necessary. The air can through the gaps between the peripheral narrow edges both in Planes transverse to the gas flow within the combustion chamber as well as in planes parallel to the gas flow enter inside. That cooling air that is in planes transverse to the direction of flow of the gas flow enters through the air gap, is distributed in the axial direction and thus forms one Cooling air film on each mosaic element.

The supporting elements connecting the mosaic elements and the outer wall are of low heat

for liquid fuel,
especially in gas turbines

Applicant:

Rolls-Royce Limited,

Derby, Derby (Great Britain)

Representative:

Dipl.-Ing. F. Weickmann and Dr.-Ing. A. Weickmann,
Patent Attorneys, Munich 2, Brunnstr. 8/9

Claimed priority:
Great Britain February 26, 1954 and January 26, 1955

Lionel Haworth, Littleover, Derby,

and Ralph John Shire, Belper, Derby (Great Britain),

have been named as inventors

management. The outer support device is expediently formed by an uninterrupted outer wall, which carries the mosaic elements representing the inner wall at a distance. The outer wall or the Carrier can be skeletal, e.g. B. by a plurality of spaced axially one behind the other Rings be formed, which are connected by longitudinal rods. The entire wall construction can be located within an outer housing serving to guide the cooling gas. But it can also be used in addition or alternatively it can be ensured that between the inner wall formed by the mosaic elements and cooling gas can be routed to the outer wall. The mosaic elements have a regular shape, z. B. triangular shape, rectangular shape, Viereckfo> rm or hexagonal shape, such that in the mosaic wall between only small gaps remain for the individual elements. The mosaic elements can either be formed by separate pieces attached to the associated carrier, or they can be combined with the Brackets consist of one piece. Each mosaic element is connected to the carrier via a single one or a plurality of webs connected. Only one is useful for each individual mosaic element only connecting bridge available. The cross section of the individual connecting web is opposite to The surface of the mosaic element is small. The webs can be from one to the opposite edge of the Go through Moeaikelementes.

809 769/158

A chamber is preferably made up of a plurality of H or double T rails in a row formed, whose one (outer) transverse leg is connected to one another at the edges facing one another and the other (internal) transverse legs are slotted transversely to the longitudinal direction, in such a way that that the inner transverse legs are divided by the slots like a mosaic. The slots extend into the middle legs connecting the outer and inner legs of the Η-rails. It can be provided in the rest of the means to a flow of cooling air from the outside of the chamber to the To flow inside the chamber. The flow can partly pass through the narrow gaps between the individual mosaic elements. Is the heat-resistant inner wall part of the combustion chamber a gas turbine, so there may be openings for the introduction of secondary and tertiary air into the Chamber be provided. In addition, of course, the air can also pass through the gap between the individual Mosaic elements get into the chamber. If an uninterrupted outer wall is used, so the openings in this wall and the gaps between the mosaic elements are dimensioned so that the Pressure between the inner and outer walls of the chamber between the pressure outside the outer wall and the pressure in the chamber itself.

The webs connecting and supporting the individual mosaic elements with the outer wall can, if Desired, passage channels for cooling gases from the outside of the outer wall into the interior of the chamber exhibit. Such through channels are also suitable for the cross section that is effective for heat conduction to reduce the webs.

The drawing shows embodiments of walls of a combustion chamber. It shows

1 shows the part of a chamber wall in an oblique view,

Fig. 1 a to 1 d an outer and inner wall connecting elements in section,

Fig. Ie to Ig different embodiments an inner wall viewed from the inside,

2 shows a second embodiment of a chamber wall in an oblique view, partly in section,

Fig. 2a shows the wall of Fig. 2 in plan view during manufacture,

3 shows a third embodiment of a chamber wall in an oblique view and partial section,

Fig. 3a shows the wall of Fig. 3 in plan view, partly in section, during manufacture,

4 shows a fourth embodiment of a chamber wall in an oblique view and in partial section,

5 shows an axial section through a combustion chamber,

5 a shows the wall of the combustion chamber according to FIG. 5 in an oblique view and section,

6 shows another embodiment of a combustion chamber in elevation during manufacture,

FIG. 6 a shows a section along line aa in FIG. 6,

6 b shows a sector of the section according to FIG. 6 a on an enlarged scale,

7 and 7 a an embodiment modified compared to FIG. 6,

8 shows a combustion chamber in axial section,

FIG. 8 a shows a part of the section of FIG. 8 on an enlarged scale,

8b shows a section along line bb of FIG. 8, FIG. 8c shows the chamber of FIG. 8 in elevation,

9 shows another embodiment of a chamber in axial section.

In Fig. 1 part of the wall of the combustion chamber of a gas turbine is shown. The wall consists of the outer wall 10, which represents one boundary wall of an air duct, the other boundary wall of which is formed by a comprehensive housing 10 a. The outer wall 10 is essentially uninterrupted, but has openings 11 which are intended for the passage of combustion devices, oil burners and the like of the chamber. The openings 11 can have any shape, as shown in Fig. 1e, 1f and 1g.

A heat-resistant inner wall is arranged at a distance from the outer wall 10. This inner wall consists of a large number of elements 12 placed next to one another like a mosaic. These are at a distance of the outer wall 10. Each individual element 12 is with the outer wall 10 via a single web or Connected pin 13, which can have any shape. As can be seen from Fig. 1, la and Ib, exist the webs 13 with the associated mosaic element 12 in one piece and extend with their ends in openings in the outer wall 10 (Fig. La to Id). The openings in the outer wall are formed by beads 14 includes, which result from the punching of the openings by themselves. With these beads 14 are the webs 13 welded or brazed with copper. According to Fig. Ic is between the web 13 and the outer wall 10 a rivet connection 15 is provided. The webs 13 can, as can be seen from Fig. 1 a, fully formed be, but can also, as can be seen from Fig. 1, have a central longitudinal bore 16, which for the Supply of cooling air is intended. As can be seen from Fig. 1 b to 1 d, the holes 17 can be expand their mouths.

The surface of each individual mosaic element 12 is smaller than the surface of the outer wall, so that a large number of mosaic elements is required to cover the outer wall. The mosaic elements 12 have a regular shape, such as. B. square shape (Fig. 1 and 1 e) or hexagonal shape (Fig. 1 f) or Triangular shape (Fig. Ig), such that their facing sides are brought into close contact can and the gap between the facing edges in all cases about the same is. If the outer wall has an opening 11, there is also a corresponding opening for the through the interior wall formed by the mosaic elements is required. This opening can be formed in that a or several mosaic elements 12 are omitted or not present. The opening 11 of the outer wall is expediently larger than the opening in the inner wall formed by leaving out the mosaic element.

The webs 13 have a relatively small cross section compared to the surface of the mosaic elements 12, and thus ensure only a low heat transfer from the inner wall to the Outer wall 10.

If the mosaic elements represent 12 separate pieces, they are made of highly heat-resistant material, z. B. made of metal or ceramic material. The outer wall 10 can be made of such stainless steel Od. Like. Be formed, the temperature resistance of which corresponds to the temperatures to be expected in operation. The material from which the outer wall is made should have good thermal conductivity.

FIGS. 2 and 2a illustrate how the wall of a combustion chamber is to be produced.

A plate of greater thickness is provided between the opposite broad sides with the aid of drills 20 α with a plurality of bores 20 which run parallel to the broad sides and are parallel to each other. In addition, with the help of drills 21 a

a second series of bores 21 made, which also run parallel to the two broad sides, under lie parallel and are at an angle, expediently at right angles, to the bores 20. By these mutually angled groups of holes webs 22 are formed which the connect both broad sides with each other. One of the two broad sides is made with longitudinal and cross slits 23 and 24 provided. These slots run parallel to the axes of associated groups of holes and lie in vertical planes that are determined by these axes. Through the slots 23 and 24 are the mosaic elements 25 are formed. The facing edges of the mosaic elements 25 are not with one another connected, while the unslotted wall, in this case the outer wall, is uninterrupted and carries the mosaic elements 25 via the webs 22.

As can be seen from Fig. 2 and 2a, the distances between the holes 20 and 21 are the same. Own If the bores 20 are spaced apart from the bores 21, the mosaic elements 25 have a rectangular shape on. They can have a parallelogram or diamond shape if the holes 20 and 21 are not in the right angle, but at a different angle to each other. Is a triangular one If the shape of the mosaic elements 25 is desired, a third set of holes is required.

As can be seen from Fig. 3 and 3a, another embodiment is also possible, according to which the Mosaic elements with the load-bearing wall or parts thereof consist of a single piece. The wall According to this embodiment, a combustion chamber is H- and double-T-shaped in cross section Formed rails, which are lined up with their longitudinal edges to form cavities. the Outer transverse legs 30 of the Η-rails are connected to the adjacent longitudinal edges, for. B. by Welding. The inner transverse legs 31 of the Η-rails are on the adjacent longitudinal edges unconnected, so that through transverse slots 32, the transverse legs 31 in a plurality of mosaic elements 33 are divided. The stringed together mosaic elements are in in no way connected. With the aid of a drill 34, a plurality of bores is made, which are perpendicular to the longitudinal axis of the Η-rails and the mosaic elements 33 with the transverse legs 30 connecting webs 35 subdivide into a plurality of individual webs. Those made with the aid of the drill 34 Bores 36 are parallel to each other. The slots 32 lie in vertical planes through the axes of the bores 36 are determined.

In this case, the outer wall is therefore uninterrupted and consists of a single piece with the individual mosaic elements 33 that represent the inner wall.

According to FIG. 4, a plate 40 has a plurality of parallel ribs 42. These have recesses 41 at intervals which form a plurality of individual ribs or webs. A second plate 43 is attached to the plate 40 by 6 & welding. After the fastening has taken place, the plate 40 is provided with intersecting slots 44, whereby the individual mosaic elements 45 are formed, which are each connected to the plate 43 via a web 42.

Fig. 5 and 5 a show the inlet end of the cylindri see Combustion chamber of a gas turbine. It can be seen that part of the inner wall has a mosaic structure according to the invention.

The wall of the chamber is made in a manner similar to that described in Fig. 3 and 3a, with the Deviation that instead of a plurality of Η rails running in the axial direction of the cylinder, one only one, spiral-wound, is used. The reference numerals of FIGS. 3 and 3a also apply to the Fig. 5 and 5 a.

6, 6 a and 6 b show the combustion chamber of a gas turbine with the inlet end 60 and the outlet end 61. The body arranged between these two end parts is a skeleton, formed by a plurality of longitudinal rods 62. These are provided with rings 63 and 64 of the Front parts 60 and 61 welded. The rods 62 extend parallel to the axis of the cylindrical combustion chamber. They enclose the cylindrical combustion chamber. The distance between the rods 62 between the fastened ends is held by rings 65 which are penetrated by the rods 62 in openings 65 α. In addition, the rings 65 are welded to the rods 62. The skeleton formed by the rings 65 and the rods 62 is intended to support the walls of the chamber. Metal strips 66 of rectangular shape are used as a wall component, which have hooks or the like at their ends, which are bent around the rods 62 or encompass them. On one narrow side the strips 66 have only one hook, while two hooks are provided on the opposite narrow side at a mutual distance. In the assembled state, one hook of one strip lies between the two hooks of the other strip. The hooks can be bent using a suitable tool.

In the case of combustion chambers of gas turbines, it is often necessary to have pipe connections in the chamber walls to be provided. As can be seen from FIGS. 6 and 6 a, a connecting pipe or connecting piece 67 is provided. This nozzle is supported by a mosaic element 68, the surface of which is about four times the Surface of a normal element, e.g. B. 12 of Fig. 1, is. In the area of the inserted nozzle 67 one of the rods 62 is interrupted and the mosaic element 68 spans a larger area than that otherwise existing normal elements 66. The element 68 is otherwise in the same way to the Rods 62 attached like elements 66.

According to the construction according to the invention, the individual mosaic elements have the possibility of Expansion due to the action of heat, while the carrier, i. H. the outer wall, outside the combustion chamber lies and is relatively cool. In addition, in the construction according to the invention, in use in a gas turbine, a flow of cooling air before, which of a housing encompassing the chamber wall through the actual Wall of the chamber passes.

According to the embodiment of FIGS. 7 and 7a, the individual mosaic elements 70 consist of cast pieces. Each casting 70 is provided with a pierced extension 70 a, which is intended for inserting a rod 62. Next to the extensions 70 a , the castings 70 are provided with tongues 70 b , which are intended to engage the adjacent mosaic element 70. To produce a chamber according to FIG. 7, the procedure is such that the individual mosaic pieces 70 are lined up on the rods 62 before these rods are welded to the rings 65, as shown in FIG. The rods 62 are then attached to one of the end portions 60 or 61 of FIG. Are z. B. lined up two rows of elements 70 on the rods, a

Ring 65 pushed on, connected to the rods, again two rows of elements 70 lined up etc., until finally, after placing the other end part 61 or 60, the entire chamber is formed is. As can be seen from FIG. 7, the elements 70 reach under each other. For this purpose, the elements 70 are facing away from the extensions 70 a- Side undercut. In this way, the passage of gas through the wall is reduced.

8 shows a combustion chamber for gas turbines in a longitudinal section. The outer wall of this chamber is denoted by 10 b. Otherwise, the construction is similar to that of FIGS. 5 and 5a, that is, the chamber is formed by rails with an H-shaped cross section. In a departure from the embodiment of FIGS. 5 and 5 a, the Η rails run in the direction of the longitudinal axis of the chamber. The rails therefore run in a straight line and, in contrast to FIGS. 5 and 5 a, are not wound spirally. The rails are connected to one another with the longitudinal edges of their outer legs by welding, so as to form the outer wall 30. The longitudinal edges of the inner legs of the rails are not connected to one another. The inner legs of the Η rails are furthermore divided into a plurality of mosaic elements 33 by slots 32 α running in the circumferential direction. The slots extend into the middle legs 35 of the H-rails, which connect the mosaic elements 33 to the outer wall 30.

Next to the inflow, the rails have no middle legs and no inner legs, so that an end part 30 α is formed which tapers conically in the direction of the inlet end.

Openings 37 in the outer wall 30 allow air to be fed into the cavities between the webs or middle legs 35.

The middle legs 35 can moreover be divided into a plurality of webs which are axially separated from one another are divided, in that the outer wall 30 is provided with slots running in the circumferential direction, which extend radially inward through the central leg] 35. Rings 38 can be inserted into these slots and be welded. These rings form axially separate compartments.

The entire wall of a chamber can have openings for the supply of air and similar purposes exhibit. Such openings are provided with lining 39. This sleeve-like lining have a larger diameter at the outer end than at the inner end.

In Fig. 9 the part of the wall of a combustion chamber is shown. The wall consists in this Trap made of annular curved rails with an H-shaped cross-section. The front edges of the outer legs 71 are connected to adjacent legs by welding to form the coherent outer wall 72 to form. The inner legs of the annularly curved rails are divided into mosaic elements 73. The middle limbs connecting the outer limbs 71 and the mosaic elements 73 are with Slits 74 are provided which also extend into the central legs of the rails. So each is Mosaic element 73 is connected to the outer wall 72 by a web in each case. The middle part 72 of the Outer wall can of course be formed by other rings of H-shaped cross-section. Openings 75 the outer wall 72 ensure an entry of air into the space between the outer wall 72 and the mosaic elements 73.

The surface size of the mosaic elements can be different, and one will use a medium size. If the surface is too large, there is a risk that the elements will sink inwards under the influence of their own weight if they overheat too much. The elements will therefore be given a surface area that excludes such sinking, but is as large as possible in order to reduce the production costs. The surface area of 0.90 cm ² will probably be a suitable size. The distance between the inner wall and the outer wall will expediently be 0.38 cm.

A combustion chamber with walls equipped according to the invention will have an increased service life have, which is very desirable because the walls of gas turbines of the latest design the combustion chambers have a shorter service life than the highly stressed turbine blades. In the embodiments shown, the supply of secondary and tertiary air takes place in the interior of the combustion chamber through the heat-resistant mosaic elements, namely from the housing encompassing the chamber. For this purpose are in the outer load-bearing wall Openings of such size in relation to the gaps between the mosaic elements are provided that the pressure between the outer wall and the mosaic elements between the pressure on the outside the outer wall and the inside of the chamber. The mosaic elements, via webs, ribs or the like. With connected to the outer wall, have the effect of preventing the outer wall from overheating Radiation and convection and reduce the amount of heat carried by conduction to the outer wall Warmth. It follows that the outer wall of a combustion chamber has a thin wall thickness and can be made of a material that can withstand these low outside temperatures. Breaks a mosaic element, it can be when discharged through the turbine, taking into account its small size cause only relatively minor damage.

Claims (22)

Patent claims: 1. Combustion chamber for liquid fuels, especially in gas turbines with a combustion chamber surrounding inner wall, which at least in part consists of a large number of in mutual spaced flat sections with straight narrow edges formed Scope exists, with each section separately due to only a limited heat transfer from the interior to the outside allowing support elements on an outer support device is held, characterized in that the distances between the individual sections (12) are formed by air gaps directly adjoining the circumference of the sections (12) and the sections on the side facing the interior are in alignment with one another and are not offset Form a surface from mosaic elements. 2. Combustion chamber according to claim 1, characterized in that the outer support device is formed by an uninterrupted outer wall. 3. Combustion chamber according to claim 1 and 2, characterized in that as a carrier element for the mosaic elements each at least one standing at right angles to the plane of the latter, with the External wall connected web of smaller cross-section than the surface of the individual mosaic element serves. 4. Combustion chamber according to claim 1 to 3, characterized in that the web or webs with the mosaic elements consist of one piece and the outer wall supporting the mosaic elements has openings for receiving the webs. 5. Combustion chamber according to claim 1 to 4, characterized in that the web ends with the load-bearing outer wall are welded or riveted. 6. Combustion chamber according to claim 1 to 5, characterized in that the mosaic elements and the webs (22) with the supporting uninterrupted outer wall (26) consist of one piece, through intersecting holes (20, 21) lying approximately parallel to the wall surface and intersecting slots (23, 24) are formed on one of the two broad sides of the wall. 7. Combustion chamber according to claim 1, 3 and 6, characterized in that the webs (13) in their Have longitudinal channels (16 or 17) intended for guiding cooling gas, which expediently expand in the direction of their mouths. 8. Combustion chamber according to claim 1 and 2, characterized in that the mosaic elements with the outer wall connecting support elements through continuous ribs (42) of the wall (40) are formed. 9. Combustion chamber according to claim 1, characterized in that they adjoin one another running, in cross-section H- or double-T-shaped rails (30, 31) is formed, whose abutting longitudinal edges of the outer transverse legs (30) are connected to one another and their inner transverse legs (33) are provided with slots (32) running transversely to their longitudinal direction are such that between the outer and inner transverse legs of the abutting Rails for cooling gas flow certain cavities are included and the mosaic elements are formed by the inner legs divided by the slots (32). 10. Combustion chamber according to claim 1 and 9, characterized in that the transverse slots (32) extend into the middle limbs connecting the outer limbs (30) and inner limbs (33), such that the majority of the mosaic elements formed by the transverse slots over Individual webs (35) are connected to the outer wall (30). 11. Combustion chamber according to claim 1, 9 and 10, characterized in that the H-shaped Rails, forming a cylindrical chamber, are spirally wound or one rail each is bent into a ring and the plurality of such rings are next to each other in the axial direction lies (Figs. 5 and 9). 12. Combustion chamber according to claim 1 to 10, characterized in that the rails of the longitudinal axis the cylindrical chamber are arranged running parallel, the abutting longitudinal edges the outer legs (30) are connected to one another and the inner legs (33) in the Have slots (32 a) which run in the circumferential direction and also penetrate into the center leg (35) (Fig. 8). 13. Combustion chamber according to claim 1 and 12, characterized in that the outer legs (30) of the H-shaped rails running in the circumferential direction, dividing the central legs Have slots and in the slots dividing the cavities between the central legs Rings (38) are used. 14. Combustion chamber according to claim 1 to 13, characterized in that the through the outer leg (30) has formed outer wall for the introduction of cooling air certain perforations (37). 15. Combustion chamber according to claim 1 and 11, characterized in that the inner legs of the axially one behind the other forming rails are divided by slots and parts are connected to the free end edges of the outer leg of a ring (Fig. 9). 16. Combustion chamber according to claim 1 and 2, characterized in that the one plate (43) formed outer wall is attached to a plurality of parallel ribs, which with one from another plate (40) formed inner wall consist of one piece, wherein the inner wall, divided by transverse slots (44), represents the entirety of the mosaic elements (45) (Fig. 4). 17. Combustion chamber according to claim 1, characterized in that the carrier device of the Mosaic elements is formed by a skeleton (62,65) which carries the mosaic elements (66). 18. Combustion chamber according to claim 1 and 17, characterized in that the skeleton by a A plurality of rings (65) is formed by axially extending rods (62) in mutual Are kept at a distance. 19. Combustion chamber according to claim 1, 17 and 18, characterized in that the Moeaik elements (66) the skeleton rods (62) have comprehensive approaches as support elements. 20. Combustion chamber according to claim 1 and 17, characterized in that the lugs (70 a) of the mosaic elements (70) serving as carrier elements have perforations for the rods (62) to pass through. 21. Combustion chamber according to claim 1, 17, 18 and 20, characterized in that the mosaic elements on the mutually facing sides have tongues (70 b) engaging in undercuts of the neighboring element as carrier elements. 22. Combustion chamber according to claim 1 and 21, characterized in that the mosaic elements the Have the shape of a regular triangle, rectangle, square or hexagon. Considered publications:
German Patent No. 863 153;
British Patent Nos. 700,004, 597 151;
U.S. Patent No. 2,548,485. For this purpose 2 sheets of drawings © 809769/153 3.59