This invention relates to dampers for gas turbines, and particularly to dampers for gas turbines where the main neck and the damper volume wall are not connected.
In existing gas turbines, dampers (or Helmholtz dampers) are normally provided to reduce pulsations and vibrations within the gas turbine combustion chamber. These dampers provide a damper volume attached to the combustion chamber by a damper neck. However, this arrangement has the drawback that the neck and the mechanical connections holding the damper in place need to be designed to tolerate thermal expansions and thermal loads. This requires extra complexity and expense in damper design and manufacture. We have therefore appreciated that it would be desirable to provide an improved damper design.
The invention is defined in the appended independent claims to which reference should now be made. Advantageous features of the invention are set forth in the dependent claims.
A first aspect of the invention provides a damper for a gas turbine combustion chamber, comprising a damper volume wall defining a damper volume inside the damper volume wall, and a main neck, the main neck comprising a main neck wall defining a main neck volume inside the main neck wall, and the main neck being associated with the damper volume for fluid communication between the damper volume and the gas turbine combustion chamber, the damper further comprising a gap between the main neck wall and the damper volume wall. As a result, the damper neck (the main neck connected to the combustion chamber) is mechanically disconnected from the rest of the damper structure. This allows for independent thermal expansion and movement of the damper neck together with the combustion chamber wall independently of the damper structure. As the damper neck and combustion chamber are in an area subject to high temperatures and the damper volume is in an area subjected to comparatively lower temperatures, this allows for independent thermal movement in these components without structural stress.
In one embodiment, the damper additionally comprises a second damper volume wall defining a second damper volume arranged outside the main neck wall, and the second neck is for fluid communication between the first damper volume and the second damper volume. This is more space efficient than previous designs, since the necks are arranged around each other.
In another embodiment, the gap and the main neck are coaxial. In another embodiment, the gap is disposed adjacent to the main neck. In another embodiment, the full circumference of the main neck is surrounded by the gap.
In another embodiment, a purge air hole is provided for providing a fluid to the second damper volume. This improves the damping performance of the damper, and allows the damper to be cooled.
In another embodiment, the gap is partly defined by a flange.
In another embodiment, a combustion chamber comprising the damper described above is provided. Preferably, the main neck is connected to a wall of the combustion chamber. Preferably, the first volume wall is connected to the combustion chamber. Preferably, the first volume wall is connected to the combustion chamber at a point distal from the main neck.
In another embodiment, a gas turbine is provided, comprising a damper as described above or a combustion chamber as described above.
A second aspect of the invention comprises a method of operating a gas turbine, according to any of the apparatus described above, the method comprising the step of feeding purging fluid through a gap between the main neck wall and the damper volume wall. In an embodiment, the method additionally comprises feeding the purging fluid through the main neck from the damper volume into the combustion chamber. In another embodiment, the method comprises the additional step of feeding purging fluid through a purge hole into the second damper volume. In another embodiment, the purging fluid is a cooling fluid such as air.
An embodiment of the invention will now be described by way of example only and with reference to the accompanying drawings in which:
A damper 1 for a gas turbine combustion chamber as shown in
A damper 10 as shown in
In the embodiment shown in
In
The damper 1, 10 and damper volume 2, 12 may be a wide variety of shapes and sizes, such as the substantially cuboid structures shown in the Figures, a substantially semi spheroid shape, or any other appropriate regular or irregular shape. In most cases, the design will be driven by the requirement to fit within available spaces around the combustion chamber within a gas turbine, and will therefore follow the contours of the combustion chamber and/or other features within the gas turbine. The design may also depend on which damping modes need damping. A similar variety of shapes is possible for the other volumes provided within the damper.
Although two damper volumes 12 and 14 are shown in
Various different arrangements of features are possible to delineate the second damper volume 14. For example, in the case shown in
The main neck 18 provides fluid communication between the damper volume and the combustion chamber, and is not connected directly to the other features of the damper. The main neck typically has an exit into the combustion chamber at one end and an exit into the damper volume at the other end. The main neck is shown as cylindrical and perpendicular to the combustion chamber wall in the Figures, but may be another shape, such as a cuboid or an irregular shape. Generally the axis of the main neck will be substantially perpendicular to the combustion chamber wall. The main neck is also not necessarily completely straight, in which case the main neck axis would preferably be defined as perpendicular to the cross-sectional plane across the main neck at the point where the main neck enters the combustion chamber.
The second or intermediate neck 7, 16 is disposed around the main neck, so that the second neck is outside the main neck. The intermediate necks are shown as cylindrical in the Figures, but may be another shape, such as a cuboid or an irregular shape. Preferably, each intermediate neck entirely surrounds the main neck, going around its full circumference. Although the examples in the Figures show the intermediate necks adjacent to the main neck, this is not essential and the intermediate neck could be separated from the main neck, for example by placing the intermediate neck part way along the secondary wall 32 of
Preferably, in any given radial direction, the intermediate neck (or gap) is disposed further from the main neck axis than the main neck. Preferably, when looking at a cross-section of the damper, the intermediate neck and the main neck lie within the same plane, the plane being perpendicular to the main neck axis; in other words, the plane includes a full cross-section of both the intermediate neck and the main neck.
The main and intermediate necks are optionally coaxial and/or concentric. In some embodiments, the main and intermediate necks have parallel axes.
The intermediate necks in the Figures are shown adjacent to the main neck, but as mentioned above this is not necessarily the case. The main requirement is that the intermediate neck should normally be as close to the combustion chamber as the main neck. At the least, the part of the intermediate neck closest to the combustion chamber should be closer to the combustion chamber than the part of the main neck furthest from the combustion chamber.
Necks have a cross-sectional area and a length, as is typical in Helmholtz dampers. The area and length define a damping frequency when combined with a volume. Extra dampers could be stacked on the damper of the current invention, either dampers according to the current invention or conventional dampers. These dampers would be attached distal to the combustion chamber.
The damper could be related to any part of the combustion chamber 6, 20.
A flange 24 is preferably provided to delineate the intermediate neck. This provides options in defining the neck length and therefore the damping frequency.
The gap 7 in
In a method of operating a gas turbine comprising the apparatus described above, purging fluid is fed through a gap 7 between the main neck wall 4 and the damper volume wall 3. It may subsequently be fed through the main neck from the damper volume 2 into the combustion chamber 6. In embodiments with a second damper volume, the method comprises the additional step of feeding purging fluid through a purge hole 26 into the second damper volume.
Various modifications to the embodiments described are possible and will occur to those skilled in the art without departing from the invention which is defined by the following claims.
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