DE102011052413A1 - Combustion chamber device or thrust chamber device - Google Patents

Abstract

There is provided a combustion chamber device or push chamber device comprising a first wall device defining an inner side of a combustion chamber or a thrust chamber and a second wall device facing an inner side of an outer side of the first wall device, wherein the first wall device is made of a ceramic composite material and a cooling channel direction for cooling the first wall device with a cooling fluid, which comprises at least one cooling channel, which is arranged or formed on the first wall device and / or the second wall device and / or between the first wall device and the second wall device, wherein in first wall means fibers of high thermal conductivity are arranged, which are arranged in the heat transport direction away from the inside and which have a thermal conductivity of at least 100 W / mK.

Description

The invention relates to a combustion chamber device or Schubkammervorrichtung.

From the EP 1 748 253 A2 is a combustion chamber, comprising an outer jacket and an inner jacket, which defines a combustion chamber and which is fluid-permeable for effusion cooling or transpiration cooling, wherein the inner jacket comprises a plurality of successive disc elements along an axial axis.

In a combustor device, a fuel is burned with an oxidizer and combustion gases can create a boost. A combustion chamber device is a specific example of a thrust chamber device. A thrust can be generated via gases, even if no combustion takes place, for example by heating a gas in a manner other than nuclear.

The invention has for its object to provide a combustion chamber device with high structural stability and high temperature resistance.

This object is achieved in that a first wall means is provided which defines a combustion chamber or a pusher space with an inner side, and a second wall means is provided, which faces with the inside of an outer side of the first wall means is provided, wherein the first Wall device is made of a ceramic composite material, and a cooling channel device for cooling the first wall device with a cooling fluid, which comprises at least one cooling channel, which arranged on the first wall means and / or the second wall means and / or between the first wall means and the second wall means or is formed, is provided, wherein in the first wall means fibers of high thermal conductivity are arranged, which are arranged in the heat transport direction away from the inside and which have a thermal conductivity of at least 100 W / mK.

A ceramic composite material such as a carbide-ceramic material or oxide-ceramic material basically has a high temperature resistance. The material has a relatively low coefficient of thermal expansion, in particular in comparison to a metallic material. If the first wall device is correspondingly thick, then it is correspondingly structurally stable and it is possible to achieve a high temperature at a hot gas side. As a result, a high temperature gradient can arise via the first wall device. However, this can lead to high thermal stresses with the corresponding material problems. According to the invention, provision is made for targeted heat conduction paths to be provided via fibers of high thermal conductivity arranged in the first heat conducting device. This can be decoupled in an effective manner from the inside of the first wall means heat in the cooling channel device, wherein a cooling fluid such as hydrogen then provides for a regenerative cooling. It can thereby achieve a high cooling efficiency with high structural integrity.

The fibers of high thermal conductivity have a thermal conductivity (in particular integral thermal conductivity) of at least 100 W / mK, preferably at least 300 W / mk, and in particular up to more than 600 W / mK. This allows effective heat dissipation to be achieved.

The fibers of high thermal conductivity are arranged protected in the matrix of the ceramic composite.

In particular, fiber ends of fibers of high thermal conductivity terminate at or near the inside of the first wall device. It can thereby provide effective heat conduction paths along the respective fibers. Furthermore, for example, the inside can then be sanded off well and a homogeneous, rough surface can be obtained, which in turn is a good carrier for a coating.

It is particularly advantageous if fibers of high thermal conductivity are guided from the inside of the first wall device to the at least one channel. This effectively dissipates heat into a channel in which a cooling fluid flows.

It is also favorable if fiber ends of fibers of high thermal conductivity terminate at a flow space or in the vicinity of a flow space of the at least one channel. This provides an effective heat conduction path across a fiber.

Conveniently, the at least one channel has an extension direction which is at least approximately parallel to an axial axis of the first wall device. It is advantageous if a cooling fluid is guided against a main flow direction in the combustion chamber or pusher chamber. As a result, effective cooling in countercurrent principle can be achieved. Furthermore, for example, a cooling fluid, which is then used as fuel, can be preheated.

In one embodiment, it is provided that fibers of high thermal conductivity are aligned at least approximately in the radial direction with respect to an axial axis of the first wall device. As a result, when the first wall means has a uniform thickness, it is possible to provide a heat conduction path of minimized length, and thereby heat can be effectively dissipated. Not all fibers have to be aligned radially. In particular, it is provided that the majority of the fibers (for example, more than 70%) are aligned at least approximately radially.

The first wall device is designed in particular as an inner liner. The second wall device surrounds the first wall device. The second wall device is designed in particular as an outer liner.

In one embodiment, a plurality of cooling channels, which are spaced in a circumferential direction, are formed on the first wall device in the region of the outside. The cooling channels are thereby integrated in the first wall device, which in particular has a meandering course at its periphery.

It is advantageous if the cooling channels are arranged distributed uniformly in the circumferential direction. As a result, a uniform cooling over the entire surface of the first wall device can be achieved.

It can be provided that a thermal barrier device is arranged between the first wall device and the second wall device, in particular if the second wall device would be in direct thermal contact without a thermal barrier device. The thermal barrier device is made of a material with low thermal conductivity. It can thereby be prevented that a heat conduction path leads from the first wall device directly into the second wall device. The thermal barrier device itself may, for example, be porous, in order, for example, to achieve a transpiration cooling via cooling fluid there. The thermal barrier device is formed for example by a (surface) coating or a tubular element.

In one embodiment, the thermal barrier device is formed by at least one tubular element. This tubular element can be arranged over the first wall device so as to obtain an effective thermal decoupling from the second wall device.

For example, the fibers of high thermal conductivity are C-fibers. These fibers are obtained in the first wall means, that is, there are C-paths in the ceramic material from the inside to the outside, which are continuous and uninterrupted.

In a manufacturing technology favorable embodiment, the first wall device comprises a plurality of axially successively arranged segments. As a result, for example, a rotationally symmetrical combustion chamber can be produced in a simple manner. It is in this context on the EP 1 748 253 A2 referenced, to which reference is expressly made.

In particular, adjacent segments have different fiber orientations in a fiber reinforcement matrix. Thereby, a first wall device can be provided, which has a high thermal resistance with low thermal expansion.

For example, segments or segment groups are axially braced in the second wall device positioned. As a result, a corresponding combustion chamber device can be produced in a simple manner.

It is particularly advantageous if the first wall device is at least partially fluid-impermeable. As a result, a regenerative cooling can be effectively achieved. The cooling fluid absorbs heat and dissipates it. With a partial fluid permeability by providing corresponding channels or pores, a transpiration cooling effect can be achieved at certain points. For example, it is also possible for cooling fluid films to form locally in the combustion chamber on the first wall device. As a result, for example, locally the wall friction and the wall heat transfer can be reduced.

A fluid impermeability can be achieved, for example, by virtue of the fact that the first wall device has a fluid-impermeable coating on the outside. For example, a copper coating is provided.

Alternatively or additionally, it is possible that the material of the first wall device has closed pores or is free of pores. During the production of the first wall device, care is taken to ensure that it is free from pores or that the resulting pores are closed by appropriate impregnation.

It is particularly advantageous if a volume fraction of high thermal conductivity fibers of the first wall device is at least 30%, in particular at least 40%, in particular at least 50%, preferably at least 60% and preferably at least 65% or at least 70% achieved. As a result, a high integral thermal conductivity of, for example, more than 300 W / mK can be achieved by the first wall device.

Conveniently, the combustion chamber or pusher chamber is rotationally symmetrical to an axial axis. This results in effective flow conditions.

The first wall device is produced in particular from a carbide-ceramic or oxide-ceramic material or highly heat-conductive carbon material (such as C / C). The carbide-ceramic material may be, for example, a C-XC or C / C-XC carbide material where X is a carbide former such as silicon.

In one embodiment, it is provided that the second wall device is made of a fiber composite material. The combustion chamber device can thereby be produced with a low weight.

It may be favorable if the first wall device is coated on the inside. The coating material used is a material with high temperature resistance and the highest possible thermal conductivity. This avoids "hot spots" with the corresponding material problems. In particular, a ceramic material is used. As a result, a higher temperature gradient can be built up via the first wall device in order to ensure effective heat transport.

It may also be favorable if the first wall device is coated on the outside. As a result, on the one hand, a fluid impermeability of the first wall device can be achieved. It is thereby also possible, when a material of high thermal conductivity, such as a metallic material such as copper, is used as the coating material to ensure uniform heat distribution on the outside of the first wall device.

As the cooling fluid, for example, hydrogen or methane is used. The correspondingly preheated cooling fluid can then be used as fuel.

The following description of preferred embodiments is used in conjunction with the drawings for further explanation of the invention. Show it:

1 a schematic sectional view of an embodiment of a combustion chamber device or Schubkammervorrichtung invention;

2 2 is a schematic representation of a segment group of a first wall device (FIG. 2 (c) ) and a manufacturing process;

3 a section of a first wall device and second wall device ( 3 (a) ) and an enlarged sectional view of a section of the first wall device ( 3 (c) );

4 a schematic representation of a portion of the first wall means and the second wall means with a flow path;

5 a plan view of another embodiment of a first wall device.

A first embodiment of a combustion chamber device according to the invention, which in a sectional view schematically in 1 shown and there with 10 includes one as a whole 12 designated combustion chamber. The combustion chamber has a combustion chamber 14 on. This combustion chamber 14 is in particular rotationally symmetrical to an axial axis 16 is trained. The combustion chamber 12 is a suitable injector device 46 assigned by which fuel and oxidizer in the combustion chamber 14 are inflatable. In the combustion chamber 14 a combustion takes place for the corresponding thrust generation.

The combustion chamber device 10 has a nozzle device 18 which is in a main flow direction 20 (see 4 ) connects to the combustion chamber. The nozzle device 18 has a nozzle space 22 which is rotationally symmetrical with an axis which is coaxial with the axial axis 16 is.

The nozzle device 18 has a cross-sectional constriction 24 compared to the cross section of the combustion chamber 14 , which is an extension 26 followed. About the nozzle device 18 a corresponding thrust is generated by means of combustion gases produced during combustion.

A combustion chamber device is a special case of a thrust chamber device. A thrust chamber device can produce a thrust, whereby combustion does not necessarily have to take place for thrust generation. For example, gases in a push chamber of a push chamber device may be heated via nuclear decomposition processes.

In the inventive solution combustion chamber and thrust chamber are basically the same.

The combustion chamber 12 comprises a first wall device 28 , The first wall device is made of a ceramic composite material (CMC material). The first wall device 28 has an inside 30 on which the combustion chamber 14 limited. It also has an outside opposite the inside 32 on.

The first wall device 28 extends along the axial axis 16 , It is along this axial axis 16 closed trained. In 1 are for representational reasons three segment groups 34a . 34b . 34c shown as not connected. In fact, the individual segment groups are connected to each other, so that the first wall device 28 an inner liner (inner shell) for the combustion chamber 14 forms.

The segment groups can be permanently connected to one another, for example by adhesive bonding or ceramic joining, or they can be detachably connected to one another; For example, they can be clamped by an axial clamping pressure.

The combustion chamber device 10 includes a second wall device 36 , which is formed closed and the first wall device 28 surrounds. The second wall device 36 has an inside 38 which of the outside 32 the first wall device 28 is facing. Furthermore, it has one of the inside 38 opposite outside 40 , The second wall device 36 is an outer liner (outer shell) of the combustion chamber device 10 , The combustion chamber 12 with the first wall device 28 is in the second wall device 36 , which is formed closed, arranged.

The first wall device 28 sits in one embodiment between an end face 42 the nozzle device 18 and a front side 44 an injector device 46 , The injector device 46 is in turn by a flange 48 held, which via fasteners 50 like bolts or the like on the second wall device 36 is fixed. The front ends 42 and 44 are in particular designed as annular surfaces. Between these sits the first wall device 28 axially jammed.

The material of the first wall device 28 has a smaller (in particular substantially lower) modulus of elasticity in the axial direction compared to a radial direction 52 perpendicular to it. As a result, it is possible to achieve a type of axial "spring action" and the first wall device 28 can be axially between the end faces 42 and 44 Pretension. The first wall device 28 can thereby be inserted loosely and it can also achieve a mechanical decoupling of the second wall means.

At the in 1 shown embodiment is as a whole with 54 designated cooling channel device provided which one or more cooling channels 56 includes, through which a cooling channel fluid on the outside 32 the first wall device 28 is past, to a regenerative cooling of the first wall device 28 to reach.

The cooling channel 56 or the cooling channels 56 are as recesses on the second wall device 36 on the inside 38 formed or between the first wall device 28 and the second wall device 36 formed and run along the outside 32 at the first wall device 28 along. A corresponding cooling channel 56 is at least approximately parallel to the axial axis 16 oriented.

There may be several spaced cooling channels 56 be provided, which circumferentially around the first wall device 28 are arranged distributed and arranged in particular evenly distributed. It is also possible for a cooling channel 56 is provided, which annular the first wall means 28 surrounds.

In one embodiment, the first wall means 28 a plurality of in the axial direction 16 successively arranged segments 58 which are in particular ring segments. Neighboring segments 58 are connected to each other and in particular integrally connected. There can be several segments 58 to segment groups 34a . 34b . 34c be connected, with adjacent segment groups 34a . 34b respectively. 34b . 34c are in turn connected to each other and in particular are integrally connected to each other.

In an embodiment which is in the 2 schematically indicated are segments 58 or a segment group 34a etc. made of ceramic composite material by first layers 60 a precursor material are made. The layers 60 include fiber scrims (or fiber fabric or Fasergewirke 62 ) with, for example, perpendicular to each other oriented fibers. In 2 B) are 0 ° / 90 ° fiber layers 62 indicated. Neighboring locations 60 have a different fiber orientation. For example, the fiber orientation with respect to adjacent layers is ± 45 °. This is in 2 B) indicated. A fiber fabric adjacent to the fiber fabric 64 is also a 0 ° / 90 ° fiber layer, with a ± 45 ° orientation.

Basically, the layers can 60 be oriented at any angle to each other. The individual fibers within a layer 60 can be oriented at any angle to each other.

There are several layers 60 built up. This can be done for example in a form. Such a stack 66 ( 2 (a) ) is infiltrated with a carbon precursor material and in particular a resin material or the fiber fabric 62 are already provided with such a carbon precursor material (prepreg scrim). From such a pile 66 Then, after curing of the carbon precursor material, a precursor segment group 68 cut out. The cutting can be done before pyrolysis of the stack 66 or after pyrolysis. If clipping occurs before pyrolysis, then the precursor segment group is 68 a resin fiber fabric body (resin fiber fabric body, resin fiber fabric body, etc.). If cleavage occurs after pyrolysis, then the precursor segment group body is a carbon body.

The corresponding carbon body after pyrolysis is then ceramified. For example, a ceramization by means of the LSI process (liquid silicon infiltration), in which the porous carbon body liquid silicon is supplied. This liquid silicon reacts with carbon to form silicon carbide. A carbide-ceramic C / C-SiC body is then formed when the fibers of the fiber scrim 62 . 64 Carbon fibers and in which a precursor polymer plastic matrix was converted to carbon. In alternative ceramization processes, such as CVI, LPI, etc., a C-SiC material is usually produced. In such ceramization processes, the carbon fibers react only marginally with the silicon.

Instead of silicon, another carbide former can also be used.

Usually shrinkage occurs during pyrolysis. It is therefore advantageous if the pyrolysis on the stack 66 is performed and then the precursor segment group body 68 will be produced.

It can be the first wall device 38 in one piece or it will be multiple segment groups 34a . 34b . 34c produced. It is also possible to prepare various precursor segment-group bodies, which are then joined to one another, for example during ceramization, or glued for example. The segment groups 34a . 34b . 34c or precursor segment group bodies 68 can be clamped axially against each other with guaranteed centering only by external tension.

In 3 (a) is a section of the combustion chamber 12 shown. In 3 (b) a section of the first wall means is shown schematically. Different segments 58 have different fiber orientations (cf. 2 B) ).

According to the invention, it is now provided that in the first wall device 28 fibers 70 high thermal conductivity are arranged. The thermal conductivity (integral) is at least 100 W / mK and preferably at least 300 W / mK. For example, it can reach 1000 W / mK or more. The fibers 70 high thermal conductivity are in a heat transport direction 72 from the combustion chamber 14 (or Schubraum) aligned away.

The fibers 70 high thermal conductivity, for example, C-fibers. They are as fibers in the first wall device 28 receive. The C fibers are retained during pyrolysis. An oxidation protection for the operational use can be achieved if required by ceramization with Carbidbildner, or by introducing additional oxidic fiber components or matrix components.

The fibers 70 high thermal conductivity extend from the inside 30 to the outside 32 in a cooling channel 56 , A corresponding fiber 70 ends with a corresponding fiber end on the inside 30 and with the opposite fiber end in a flow space 74 of the corresponding channel 56 , The corresponding fiber ends can be directly on the inside 30 or outside 32 or there may still be a corresponding coating there, as will be explained in more detail below.

fibers 70 high thermal conductivity (especially all or most of the fibers 70 high thermal conductivity) are transverse and in particular perpendicular to the axial axis 16 oriented. fibers 70 high thermal conductivity are in particular radially (that is, parallel to the radial direction 52 ) oriented. In particular, most of the fibers are 70 high thermal conductivity oriented in at least approximately radial direction. The radial direction 52 is a direction in which the distance between the inside 30 and the outside 32 is the smallest.

It can also be fibers 70 be provided high thermal conductivity, which are not oriented in the radial direction.

It is specifically intended that fibers 70 high thermal conductivity in the first wall device 28 at least 30%, preferably at least 40% and especially preferably at least 50% and preferably at least 55%, or at least 60%, or at least 65%. In one embodiment, the volume fraction is about 70%.

Through the fibers 70 high thermal conductivity can be in the heat transport direction 72 targeted heat from the inside 38 in the cooling channel device 54 dissipate. This in turn allows the combustion chamber to be effectively controlled 12 or thrust chamber to regeneratively cool.

Basically, it is such that, in order to overheat the first wall device 28 to prevent the corresponding wall material must have a high temperature resistance and must have a high thermal conductivity. The more stable and, above all, the thicker the first wall device 28 is, the higher the temperature at a hot gas side, that is on the inside 30 , A high local temperature gradient usually means that high thermoelectric voltages are present, which in turn can lead to material problems (in particular material fatigue). On the one hand, a ceramic composite has high temperature resistance and low thermal expansion. The combination of high temperature resistance, high thermal conductivity and low thermal brittleness enables high temperature gradients across the wall profile from the hot gas side to the cooling channel 56 , High temperature gradients also allow a certain and necessary heat dissipation in the first wall device 28 at already lower thermal conductivities and greater wall thicknesses than, for example, metallic wall structures.

By providing fibers 70 high thermal conductivity to provide defined heat transport paths and thus to increase the integral thermal conductivity, you get a high cooling efficiency with high structural integrity.

It is basically provided that the first wall device 28 is formed fluid-tight. This can be achieved in different ways. In one embodiment, the first wall means 28 on the outside 82 a fluid-impermeable coating. Alternatively or additionally, it is possible that the material of the first wall device 28 has closed pores, or is pore-free. If there are pores, they can be closed by a suitable impregnation. It can be ensured, for example, during the ceramization that the ceramic material is pore-free or has closed pores.

It can be provided that the first wall device 28 partially permeable is between the combustion chamber 14 (or pusher space) and the cooling channel device 54 , As a result, cooling fluid, which in particular is fuel such as hydrogen, can flow through the first wall device into the combustion chamber 14 reach. This allows a certain amount of perspiration through the first wall device 28 in certain areas. This in turn can be a transpiration cooling done at these specific areas and it may, for example, a film of cooling fluid on the inside 30 the first wall device 28 in certain areas. Such a film reduces, for example, the wall friction and thereby reduces throttle losses. It can, as explained, also take place an additional cooling effect via transpiration cooling.

The inside 30 and the outside 32 can be easily sanded and coated, as fiber ends on the inside 30 and the outside 32 end up. This can not lead to the splicing of fibers. An abrasive surface then has a homogeneous roughness. In turn, coatings can be applied with good adhesion. For example, sputtered layers, plasma coatings, electroplated coatings, etc. can then be produced.

In one embodiment, the outside is 32 with a coating 76 , as in 3 (c) indicated, provided. The coating 76 is in particular made of a metallic material and extends over the entire outside 32 ,

This results in a fluid-tight design of the first wall device 28 reached.

By providing the coating 76 From a metallic material of high thermal conductivity such as copper is achieved that a homogeneous temperature distribution on the outside 32 the first wall device 28 formed. This, in turn, causes local peak loads on the material of the first wall device 28 prevented.

The inside 30 can with a coating 78 (see 3 (c) ) be provided. This coating is preferably made of a material with high heat transfer to the first wall device 28 produced. In particular, it is made of a ceramic material (carbide-ceramic or oxide-ceramic). One possible material is silicon carbide, for example. By using such a material which has a high temperature resistance, a higher temperature gradient can occur between the inside 30 and the outside 32 be achieved. Such a higher gradient, in turn, provides effective heat transfer and thereby effective cooling effect.

The fibers 70 in the first wall device 28 are effectively protected in a matrix, the ceramic composite, protected arranged.

As mentioned above, the first wall means 28 for example, be made of a carbide-ceramic material. It can also be made, for example, from an oxide ceramic material.

The combustion chamber device works as follows:
The combustion chamber device 10 is explained in an example in which in the combustion chamber 14 a combustion takes place. Hydrogen and oxidizer are via the injector device 46 in the combustion chamber 14 coupled. A mainstream direction 20 in the combustion chamber 14 is parallel to the axial axis 16 (see 4 ). For example, in a combustion chamber area 80 ( 1 ), the subsonic flow, that is, there is a subsonic flow. At the nozzle device 18 is due to the areas 24 . 26 a supersonic flow area 82 in front.

Cooling fluid, in particular hydrogen, is passed through the cooling channel (s) 56 in a flow direction 84 performed, which counter to the main flow direction 20 in the combustion chamber 14 is. The cooling fluid absorbs heat via the first wall means 28 is provided, and is thereby preheated. The preheated cooling fluid, if it is fuel, then passes over the injector device 46 in the combustion chamber 14 injected. The cooling fluid is, for example, hydrogen and in particular liquid hydrogen. About the fibers 70 High thermal conductivity will effectively heat from the inside 30 to the outside 32 the first wall device 28 dissipated.

The flow direction 84 can also be performed in the opposite direction.

For example, in an expander cycle of a European VINCI-Oberstufentriebwerks the preheated fuel before injection at an injector is still used by enthalpy for the operation of turbopumps, that is fuel, which in the corresponding (regenerative) cooling channel device, which associated with a combustion chamber or thrust chamber is, was heated, the absorbed enthalpy while flowing through a turbine to this before the fuel is injected in an injection head into the combustion chamber. With the fuel, a turbo pump is then operated during the expander cycle. A flow direction of the cooling fluid may be parallel to the main flow direction of a hot gas flow in the combustion chamber (co-flow) or opposite (counter-flow).

In a further embodiment of a combustion chamber 86 , what a 5 shown schematically in a cross section and there with 86 is designated, is a first wall means 88 provided, which one about the axial axis 16 (for the same elements as the combustion chamber 12 same reference numerals are used) rotationally symmetrical the combustion chamber 90 limited. The first wall device is made of a ceramic composite material. She has an inside 92 , which limits the combustion chamber, and an outside 94 , In the area of the outside 94 are in the first wall device 88 cooling channels 96 the cooling channel device 54 educated. The cooling channels 96 are circumferentially on the outside 94 arranged. Adjacent cooling channels 96a . 96b are circumferentially spaced from each other with an intermediate web 98 , In particular, the cooling channels 96 evenly distributed around the circumference of the first wall device 88 on the outside 94 arranged.

In this embodiment, the cooling channels 96 in the first wall device 88 integrated. The first wall device 88 is thereby on the outside 94 designed corresponding meandering.

On the inside 92 and / or the outside 94 can be provided as described above, a coating.

The cooling channels 96 are parallel to the axial axis 16 oriented.

In particular, a thermal barrier device 100 be provided. This is around the outside 94 the first wall device 88 arranged. By the thermal barrier device can be a high heat input into a second wall device, which is the first wall device 88 surrounds, prevent. (Over the bridges 98 In principle, such a high heat input can take place.) The thermal barrier device 100 lies between an outside of the webs 98 and the second wall device as an outer liner. The thermal barrier device 100 is for example by a pipe element 102 formed, which over the first wall device 84 is pushed over.

The thermal barrier device 100 provides a thermal insulation layer. It is made for example of a poor heat conductive fiber ceramic material, for example, based on alumina.

It may be provided that this thermal barrier device has a certain open porosity. Then this thermal barrier device can be used 100 saturate with "cold" cooling fluid and cool additionally.

Otherwise, the combustion chamber works 86 as described above.

The combustion chamber device according to the invention is for example part of a drive device of a missile and in particular a rocket.

LIST OF REFERENCE NUMBERS

10

 combustion chamber device

12

 combustion chamber

14

 combustion chamber

16

 Axial axis

18

 nozzle device

20

 (Main) flow direction

22

 nozzle chamber

24

 Cross-sectional narrowing

26

 extension

28

 First wall device

30

 inside

32

 outside

34a, b, c

 segment group

36

 Second wall device

38

 inside

40

 outside

42

 front

44

 front

46

 injector

48

 flange

50

 connecting element

52

 Radial direction

54

 Cooling duct means

56

 cooling channel

58

 segments

60

 documents

62

 fiber fabrics

64

 fiber fabrics

66

 stack

68

 Precursor segment groups Body

70

 fiber

72

 Heat transport direction

74

 flow chamber

76

 coating

78

 coating

80

 Combustion chamber region

82

 Supersonic flow region

84

 flow direction

86

 combustion chamber

88

 First wall device

90

 combustion chamber

92

 inside

94

 outside

96

 cooling channel

96a, b, c

 cooling channel

98

 web

100

 Thermal barrier device

102

 tube element

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• EP 1748253 A2 [0002, 0020]

Claims (27)

Combustion chamber device or thrust chamber device, comprising a first wall device ( 28 ; 88 ), which with an inside ( 30 ; 92 ) a combustion chamber ( 14 ; 90 ) or a Schubraum limited, and a second wall device ( 36 ), which with an inside ( 38 ) an outside ( 32 ; 94 ) of the first wall device ( 28 ; 88 ), wherein the first wall device ( 28 ; 88 ) is made of a ceramic composite material, and a cooling channel direction ( 54 ) for cooling the first wall device ( 28 ; 88 ) with a cooling fluid, which at least one cooling channel ( 56 ; 96 ), which on the first wall means ( 84 ) and / or the second wall device ( 36 ) and / or between the first wall device and the second wall device is arranged or formed, wherein in the first wall device ( 28 ) Fibers ( 70 ) of high thermal conductivity are arranged, which in the heat transport direction ( 72 ) from the inside ( 30 ; 92 ) and which have a thermal conductivity of at least 100 W / mK. Combustion chamber device or thrust chamber device according to claim 1, characterized in that fiber ends of fibers ( 70 ) high thermal conductivity at or near the inside ( 30 ; 92 ) of the first wall device ( 28 ; 88 ) end up. Combustion chamber device or thrust chamber device according to claim 1 or 2, characterized in that fibers ( 70 ) high thermal conductivity from the inside ( 30 ; 92 ) of the first wall device to the at least one channel ( 56 ; 96 ) are guided. Combustion chamber device or thrust chamber device according to claim 3, characterized in that fiber ends of fibers ( 70 ) high thermal conductivity at a flow space ( 74 ) or in the vicinity of a flow space ( 74 ) of the at least one channel ( 56 ; 96 ) end up. Combustion chamber device or thrust chamber device according to one of the preceding claims, characterized in that the at least one channel ( 56 ; 96 ) has an extension direction which is at least approximately parallel to an axial axis ( 16 ) of the first wall device ( 28 ; 88 ). Combustion chamber device or thrust chamber device according to one of the preceding claims, characterized in that fibers ( 70 ) high thermal conductivity at least approximately in the radial direction ( 52 ) relative to an axial axis ( 16 ) of the first wall device ( 28 ; 88 ) are aligned. Combustion chamber device or thrust chamber device according to one of the preceding claims, characterized in that the first wall device ( 28 ; 88 ) is designed as an inner liner. Combustion chamber device or thrust chamber device according to one of the preceding claims, characterized in that the second wall device ( 36 ) the first wall device ( 28 ; 88 ) surrounds. Combustion chamber device or thrust chamber device according to one of the preceding claims, characterized in that the second wall device ( 88 ) is designed as an outer liner. Combustion chamber device or thrust chamber device according to one of the preceding claims, characterized in that on the first wall device ( 88 ) in the area of the outside ( 94 ) a plurality of cooling channels ( 96 ) are formed, which are spaced in a circumferential direction to each other. Combustion chamber device or thrust chamber device according to claim 10, characterized in that the cooling channels ( 96 ) are arranged uniformly distributed in the circumferential direction. Combustion chamber device or thrust chamber device according to one of the preceding claims, characterized in that between the first wall device ( 88 ) and the second wall means a thermal barrier device ( 100 ) is arranged. Combustion chamber device or thrust chamber device according to claim 12, characterized in that the thermal barrier device ( 100 ) by at least one tubular element ( 102 ) is formed. Combustion chamber device or thrust chamber device according to one of the preceding claims, characterized in that the fibers ( 70 ) high thermal conductivity C fibers include. Combustion chamber device or thrust chamber device according to one of the preceding claims, characterized in that the first wall device ( 28 ; 88 ) a plurality of axially successively arranged segments ( 58 ) having. Combustion chamber device or thrust chamber device according to claim 15, characterized in that adjacent segments ( 58 ) have different or equal fiber orientations of a fiber reinforcement matrix. Combustion chamber device or thrust chamber device according to claim 15 or 16, characterized characterized in that segments ( 58 ) or segment groups ( 34a . 34b . 34c ) axially clamped in the second wall means ( 36 ) to sit. Combustion chamber device or thrust chamber device according to one of the preceding claims, characterized in that the first wall device ( 28 ; 88 ) is formed at least partially fluid-impermeable. Combustion chamber device or thrust chamber device according to claim 18, characterized in that the first wall device ( 28 ; 88 ) on the outside ( 32 ) a fluid impermeable coating ( 76 ) having. Combustion chamber device or thrust chamber device according to claim 18 or 19, characterized in that the material of the first wall device ( 28 ; 88 ) has closed pores or is pore-free. Combustion chamber device or thrust chamber device according to one of the preceding claims, characterized in that a volume fraction of fibers ( 70 ) of high thermal conductivity in the first wall device is at least 30%, in particular at least 40% and in particular at least 50%, in particular at least 60% and in particular at least 70%. Combustion chamber device or thrust chamber device according to one of the preceding claims, characterized in that the combustion chamber ( 14 ) or thrust chamber rotationally symmetrical to an axial axis ( 16 ) is trained. Combustion chamber device or thrust chamber device according to one of the preceding claims, characterized in that the first wall device ( 28 ; 88 ) is made of a carbide ceramic or oxide ceramic material or highly heat conductive carbon material. Combustion chamber device or thrust chamber device according to one of the preceding claims, characterized in that the second wall device ( 36 ) is made of a fiber composite material. Combustion chamber device or thrust chamber device according to one of the preceding claims, characterized in that the first wall device ( 28 ; 88 ) on the inside ( 30 ; 92 ) is coated. Combustion chamber device or thrust chamber device according to one of the preceding claims, characterized in that the first wall device ( 28 ; 88 ) on the outside ( 32 ) is coated. Combustion chamber device or thrust chamber device according to one of the preceding claims, characterized in that hydrogen or methane is used as the cooling fluid.

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