The present invention relates to the field of aircraft gas turbine combustion chambers, in particular, for helicopter.
In a known manner, with reference to
In operation, during the combustion reaction R, the temperature of the inner wall 121 is higher than that of the outer wall 122, which, due to thermal expansions, results in a relative displacement between the inner wall 121 and the outer wall 122. The bridges 104 are thereby likely to break as illustrated in
An immediate solution to eliminate this drawback would be to strengthen the linkage of each bridge, but this entails significant time and cost of manufacture. Thus, the invention aims to eliminate at least some of these drawbacks.
In prior art from patent application US20130047618A1 a double wall for a combustion chamber of a gas turbine comprising bump-shaped protrusions is known.
The invention relates to a double wall for aircraft gas turbine combustion chamber comprising an inner wall configured to be in contact with the combustion reaction and an outer wall, spaced apart from the inner wall, comprising a plurality of ports so as to allow circulation of cooling air flows, external to the outer wall, which cool the inner wall. The inner wall is free of perforation so as to prohibit any circulation of air flow to the center of the combustion chamber.
The invention is remarkable in that the inner wall comprises a plurality of members projecting towards the outer wall, each projecting member extending into a port so as to define a calibrated flow cross-section between the projecting member and the port for the passage of a cooling air flow.
Advantageously, the plurality of projecting members allows the exchange surface between the cooling air flow and the inner wall to be increased, which improves the life time of the combustion chamber. In addition, the positioning of the projecting member in a port allows a calibrated flow cross-section to be defined, which allows the cooling air flow to be accurately regulated. Finally, such projecting members do not have a significant thermal gradient during use, which increases the life time. Finally, such projecting members are used to support the inner wall during additive manufacturing.
Preferably, since each port has a peripheral edge, each projecting member extends away from the peripheral edge of the port. Thus, there is no direct heat conduction between the projecting member and the outer wall. In addition, this allows differential expansion during operation given that the wall temperatures are different.
Preferably, each projecting member is distant from the outer wall, that is without contact, so as to avoid any heat conduction. The projecting members are advantageously free in relation to the outer wall.
Advantageously, the cooling air flow circulate peripherally about each projecting member, which improves cooling. Preferably, the calibrated flow cross-section is peripheral, preferably annular.
According to one aspect of the invention, each projecting member has a flared cross-section towards the inner wall. As a result, the projecting member has a robust base, which increases the life time.
Preferably, the outer wall comprises an outer face, each projecting member having an end face extending as an extension of the outer face of the outer wall. This is advantageous given that it improves the circulation of cooling air flow by avoiding forming a relief pattern likely to lead to formation of turbulence. Such a characteristic is advantageously obtained during additive manufacturing as will be set forth later.
According to one preferred aspect of the invention, the double wall is additively manufactured. Such a manufacturing method ensures precise positioning of the projecting member in a port.
The invention also relates to a method for manufacturing a double wall as set forth previously, wherein the inner wall and the outer wall are additively manufactured.
Preferably, the inner wall and the outer wall are secured to a temporary support by incremental addition of metal powders, then unsecured from the temporary support by cutting at the interface between the walls and the temporary support. Preferably, prior to unsecuring, the assembly is depowdered and then heat treated.
The invention also relates to an aircraft gas turbine combustion chamber comprising a double wall as set forth previously, wherein the inner wall is configured to be in contact with the combustion reaction.
The invention also relates to a gas turbine, in particular for aircraft, comprising a combustion chamber as set forth previously.
The invention is also directed to a method for using a combustion chamber as set forth previously, comprising:
Preferably, as each projecting member expands thermally, each projecting member in the expanded state extends away from the peripheral edge of the port into which it extends.
The invention will be better understood upon reading the following description, given as an example, and by referring to the following figures, given as non-limiting examples, wherein identical references are given to similar objects.
It should be noted that the figures set out the invention in detail in order to implement the invention, said figures may of course be used to better define the invention if necessary.
The invention will be set forth for an aircraft gas turbine combustion chamber. With reference to
By combustion chamber, it is advantageously meant any enclosure in which a combustion reaction is carried out and whose temperature should be controlled.
As illustrated in
As illustrated in
The inner wall 21 is impermeable, that is, free of perforation so as to prohibit any circulation of a cooling air flow F towards the center of the combustion chamber 1, which would impact combustion performance. Such an inner wall 21 enables the combustion efficiency of the combustion chamber to be improved.
According to the invention, the inner wall 21 comprises a plurality of projecting members 4 towards the outer wall 22, each projecting member 4 extending into a port 3 so as to define a calibrated flow cross-section for the passage of the cooling air flow F. In this example, each port 3 is associated with a projecting member 4. It goes without saying that some ports 3 could be free of projecting member 4.
Advantageously, the projecting members 4 make it possible to increase the heat exchange surface area of the inner wall 21 with the cooling air flows F, which improves cooling of the inner wall 21. In addition, a calibrated flow cross-section allows precise control of the cooling air flow F in order to use it sparingly.
With reference to
In this example, the projecting member 4 has a flared cross-section towards the inner wall 21. A flared cross-section allows the projecting member 4 to have a wide base ensuring a robust connection with the inner wall 21.
Subsequently, with reference to
With reference to
Advantageously, the projecting member 4 is centered in the port 3 so that the calibrated cross-section is adapted between the head portion 4b and the port 30, preferably with annular shape. As the combustion chamber rises in temperature, thermal expansions will increase the flow cross-section area of the cooling air flow to achieve optimum cooling. The calibrated cross-section makes it possible to adapt the cooling air flow rate in order to use the cooling air flow sparingly.
Preferably, the radius r3 of the port 3 is greater than the radius r4 of the projecting member 4 in order to define a sufficient flow cross-section for the cooling air F. The radius r3 of the port 3 is greater than the radius r4 by at least 10%, still preferably by at least 30%, yet preferably by at least 100%. The space between the projecting member 4 and the peripheral edge 30 of the port 3 defines a clearance which allows expansion of the projecting member 4. As will be set forth later, in the expanded state, each projecting member 4 extends away from the peripheral edge 30 of the port 3 into which it extends. Therefore, any heat conduction between a projecting member 4 and the outer wall 22 is avoided. Preferably, as illustrated in
Still with reference to
Preferably, with reference to
According to an exemplary implementation, during manufacture, the walls 21, 22 are secured to the temporary support 5 by incremental addition of metal powders. The assembly is then depowdered and heat treated. The walls 21, 22 are unsecured from the temporary support 5 by cutting at the interface between the walls 21, 22 and the temporary support 5. Such additive manufacturing advantageously makes it possible to obtain original and innovative geometries while reducing thicknesses. Furthermore, such additive manufacturing does not require the use of a mold for manufacturing, which is a source of savings. It goes without saying that walls 21 and 22 could also be manufactured by a combination of mechanically welded or foundry-obtained parts.
The inner wall 21 and the outer wall 22 are then mounted in the combustion chamber 1 so as to provide a space E therebetween as illustrated in
An exemplary implementation of the invention will now be set forth with reference to
Advantageously, the cooling air flow F moves in the space E formed between the inner wall 21 and the outer wall 22 via the calibrated flow cross-section. The cooling air flow F makes it possible to come into contact with the entire surface area of the projecting member 4, which allows heat exchanges to be maximized.
Preferably, during operation, each projecting member 4 thermally expands. In the expanded state, each projecting member 4 extends away from the peripheral edge 30 of the port 3 into which it extends. Therefore, any heat conduction between a projecting member 4 and the outer wall 22 is avoided.
By virtue of the invention, the double wall 2 can be optimally cooled by cooling air flows F without the risk of creating weak or break points. The presence of projecting members 4 increases the heat exchange surface area and calibrates the flow cross-section of the cooling air flow F.
Number | Date | Country | Kind |
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2100013 | Jan 2021 | FR | national |
Filing Document | Filing Date | Country | Kind |
---|---|---|---|
PCT/EP2021/086791 | 12/20/2021 | WO |
Publishing Document | Publishing Date | Country | Kind |
---|---|---|---|
WO2022/144206 | 7/7/2022 | WO | A |
Number | Name | Date | Kind |
---|---|---|---|
4916905 | Havercroft | Apr 1990 | A |
5353865 | Adiutori | Oct 1994 | A |
10830448 | Pacheco-Tougas | Nov 2020 | B2 |
20130047618 | Gregory | Feb 2013 | A1 |
20170356652 | Singh et al. | Dec 2017 | A1 |
20170370586 | Okita et al. | Dec 2017 | A1 |
20190195496 | Moura et al. | Jun 2019 | A1 |
Number | Date | Country |
---|---|---|
3072448 | Apr 2019 | FR |
S62-35001 | Feb 1987 | JP |
Entry |
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International Search Report from corresponding application No. PCT/EP2021/086791, dated Apr. 5, 2022, 2 pages. |
French Search Report from corresponding application No. FR 2100013, dated Sep. 16, 2021, 2 pages. |
Number | Date | Country | |
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20240044492 A1 | Feb 2024 | US |