Patent Application
20200080435
The present disclosure relates generally to gas turbine engines and, more particularly, to turbine cases.
Turbine exhaust structures, sometimes called turbine exhaust cases, may be structural components of the engine, wherein they are load bearing in addition to providing aerodynamic functions. Structural turbine exhaust cases support a bearing housing and a bearing for a main spool (e.g. a low pressure spool, including the shaft and rotary components mounted thereto) of the engine. However, in seeking to provide a turbine exhaust structure having desired levels of strength and/or stiffness for airborne gas turbine engines, the potential negative weight impact of making a very strong and/or stiff turbine exhaust structure must be carefully considered by the designer.
Therefore, there remains a need for an improved turbine exhaust case structure for a gas turbine engine.
There is accordingly provided a turbine exhaust structure for a gas turbine engine, comprising: a turbine exhaust duct having annular inner and outer case portions radially spaced apart to define an annular gas path therebetween, a plurality of struts extending between and structurally interconnecting the inner and outer case portions, the struts being circumferentially spaced apart about within the annular gas path, a strut axis extending through each of the struts between a radially inner end and a radially outer end thereof; and a bearing housing disposed within the inner case portion of the turbine exhaust duct, the bearing housing adapted to support a main shaft bearing of the gas turbine engine, a plurality of structural ribs extending between the bearing housing and the inner annular case portion, the structural ribs configured to structurally interconnect and transfer load between the bearing housing and the inner case portion of the turbine exhaust duct, the structural ribs circumferentially spaced from one another and circumferentially offset from the struts.
There is also provided a method of fabricating a turbine exhaust structure of a gas turbine engine, the method comprising: integrally forming a turbine exhaust duct and a bearing housing as a single monolithic component, the turbine exhaust ducting including having annular inner and outer case portions and a plurality of struts extending between and structurally interconnecting the inner and outer case portions, the struts circumferentially spaced from one another and each defining a strut axis extending therethrough between a radially inner end and a radially outer end of the struts, the bearing housing disposed within the inner case portion of the turbine exhaust duct; and forming a plurality of structural ribs integrally with the bearing housing and the turbine exhaust duct, the structural ribs extending radially between the bearing housing and the inner case portion, the structural ribs being circumferentially spaced apart from each other, the structural ribs being axially aligned with the struts of the turbine exhaust duct.
Reference is now made to the accompanying figures in which:
In the depicted embodiment, the gas turbine engine 10 is a turboshaft engine and the turbine section 18 thereof includes a high pressure turbine 20, which drives the compressors 14 via a high pressure (HP) shaft 17, and a low pressure (LP) turbine 22 (sometimes called the power turbine 22) which provides power output to the reduction gearbox 13 via a low pressure shaft 19 for driving a power output shaft 12 of the engine.
Although the gas turbine engine 10 as depicted in
At the aft end of the engine 10, the gas turbine engine 10 further includes a turbine exhaust structure 25 located at the exit of the turbine section 18, immediately downstream therefrom. The turbine exhaust structure 25 directs the hot core exhaust gases exiting from the turbine section 18 further downstream, to exit the engine. The turbine exhaust structure 25 of the present disclosure may also be referred to herein as a turbine exhaust case (sometimes abbreviated TEC), given that these terms are often used by those skilled in the art when referring to this component of a gas turbine engine. It is however to be understood that regardless of the terminology used, all relate to the structure located downstream of the turbine section 18 of the engine, through which passes the hot exhaust gasses from the core of the engine 10.
As will also be seen in further detail below, with reference to
The outer turbine exhaust duct 28 includes an annular inner case portion 27, an annular outer case portion 29 that is spaced radially outward from the inner case portion 27, and a plurality of airfoil-shaped struts 31 radially extending between the inner and outer case portions 27, 29, thereby structurally connecting same. The airfoil-shaped struts 31 (hereinafter simply “struts” or “airfoils”) therefore extend through the hot annular gas path, and are sometimes referred to as “hot struts” by those skilled in the art. The struts 31 are circumferentially spaced apart about the annular passage 32 defined between the inner and outer case portions 27 and 29, through which the hot core exhaust gasses exiting the turbine section 18 of the engine flow. The airfoil-shaped struts 31 may be substantially hollow.
As described in further detail below, in one particular embodiment the turbine exhaust duct 28 and the bearing housing 33 of the turbine exhaust structure 25 are integrally formed as a single, monolithic structure, whether by additive manufacturing or more conventional manufacturing methods, including machining, casing, molding, etc. However, it is also possible for the various components of turbine exhaust structure 25 to be formed separately and then assembled. In this embodiment, the airfoil-shaped struts 31 may be made of sheet metal, and the inner and outer case portions 27, 29 may be formed for example by machining, forging, casting, etc.
During operation of the gas turbine engine 10, combustion gases discharged from the combustor 16 power the high and low pressure turbines 20 and 22, and are then exhausted through the annular gas path 32 defined between the inner and outer case portions 27, 29 of the turbine exhaust case 25. The tangential flow components included in the exhaust gases are de-swirled by the airfoils 31 of the turbine exhaust case 25, and then the exhaust gases are discharged downstream into the atmosphere.
In the depicted embodiment, the turbine exhaust structure 25 is load bearing, in that it supports a bearing housing 33 therein within which a bearing for a main spool of the engine (such as the low pressure spool, which may include the LP shaft 19, including the shaft and the rotary components—e.g. the rotors of the compressor 14 and the LP turbine rotor 20—mounted thereto). The turbine exhaust case 25 may therefore support a portion (and, in a particular embodiment, a major portion) of the weight of the low pressure spool, in addition to bearing its own weight and the aerodynamic loads affecting thereon by the exhaust gases.
The bearing housing 33 is disposed radially within the inner case portion 27 of the turbine exhaust structure 25, and is structurally connected, in a manner described in further detail below, to the inner case portion 27 for supporting an aft end of the low pressure shaft 17 of the low pressure spool.
The bearing housing 33 includes a generally cylindrical body defining a central bore 38 therein sized for accommodating therein a bearing of the main engine shaft (e.g. the LP shaft 19). The bearing housing 33 may also include a flange 47 radially extending from the cylindrical body at an axial end thereof, for mounting the bearing housing 33 to other structures of the engine 10.
In a particular embodiment, the bearing housing 33 is integrally formed as a single monolithic structure with a remainder of the turbine exhaust structure 25, including the inner case portion 27 of the turbine exhaust duct 28. The entire turbine exhaust structure 25 may thus be formed as a single monolithic component, whether by additive manufacturing or more conventional manufacturing methods, including machining, casing, molding, etc. In this regard, the entire design of the present turbine exhaust structure 25 is configured such as to be readily adaptable for additive manufacturing technologies. In one possible embodiment, the entire turbine exhaust structure 25 is made of the same material throughout.
An integrated turbine exhaust structure 25, having among other things an integrated bearing compartment within the inner case portion 27, permits the turbine exhaust structure 25 of the present disclosure to be compact, thereby making it suitable for small engine architectures where space between a turbine inner gas path and the bearing compartment is small and thus in situations where previously used turbine exhaust cases, having a mechanical bolted flange arrangement between the exhaust duct and bearing compartment, would not be feasible.
Referring now more specifically to
Additionally, in a particular embodiment, one or more bearing support legs 42 may also be provided to help support the bearing housing 33 within the inner case portion 27 of the turbine exhaust duct 28 and thus help bear the load of the engine spool supported by the bearing within the bearing housing 33. The bearing support leg(s) 42 may extend radially between the body of the bearing housing 33 and the inner wall 35 of the inner case portion 27. In the depicted embodiment, at least one main bearing support leg 42 is circumferentially disposed at a bottom point within between the bearing housing 33 and the inner case portion 27. Two, three or more support legs 42 may alternately also be provided.
The bearing housing 33 receives therein a main shaft bearing at the aft end of the engine 10, which in turn supports the aft end of the LP spool for example, and therefore load is transmitted from the bearing housing 33, through the ribs 40 and the support leg(s) 42, to the outer case portion 29 of the turbine exhaust duct 28. A forward-end mounting flange 39 is integrated with the outer case portion 29 of the turbine exhaust duct 28, for securing the turbine exhaust duct 28 and thus the entire turbine exhaust structure 25 to an upstream engine case (e.g. the gas generator case surrounding the combustor section 16 and turbine section 18 of the core of the engine 10).
As best seen in
In one particular embodiment, each structural rib 40 is circumferentially disposed between a pair of struts 31 that are circumferentially adjacent thereto, and disposed on either circumferential side of said each structural rib 40. In the depicted embodiment, each rib 40 is disposed circumferentially mid-way between each pair of struts 31. However, it is to be understood that alternate circumferentially offset configurations remain possible. For example, two ribs 40 may be disposed between each pair of struts 31, in which case neither of the ribs 40 would be disposed at the circumferential mid-point between the pair of struts 31. Alternately, some pairs of struts 31 may not have any ribs 40 therebetween, while others may have multiple.
While the number of ribs 40 extending radially between the bearing housing 33 and the inner case portion 27 of the turbine exhaust duct 28 may vary, in at least one embodiment the number of ribs 40 is equal to the number of struts 31 extending radially between the inner case portion 27 and the outer case portion 29 of the turbine exhaust duct 28.
Referring now to
As best seen in
Additionally, the “hot” struts are axially inclined, such that each of the “hot” struts extends along a strut axis between a radially inner end and a radially outer end of the strut, wherein the radially outer end is upstream (i.e. axially forward) relative to the radially inner end.
As can also be seen in the embodiment of
Referring still to
As best seen in
These structural features of the turbine exhaust structure 25 may accordingly provide a relatively high stiffness structure with high stiffness/weight ratio, and a compact design that can be used with small engines and/or in configurations having tight space constraints. For example, in one particular embodiment of the present turbine exhaust structure 25, a ratio of stiffness to weight (stiffness/weight) is greater than 15000 lbf/in (pound-force/inch) per 1 lb (pound mass) of material. This is sometimes referred to as specific stiffness or specific modulus.
The present turbine exhaust structure 25 may permit a compact design compared to known turbine exhaust structures, which may be particularly useful for small engines and/or applications where tight space constraints exist for the engine and/or the turbine exhaust section thereof. The present turbine exhaust structure 25 has a design which may also help save cost and/or weight compared to typical “mid-turbine” frame designs known in the art.
The above description is meant to be exemplary only, and one skilled in the art will recognize that changes may be made to the embodiments described without departing from the scope of the invention disclosed. For example, although a turboshaft engine is shown, the invention may be used with various types of gas turbine engines, including turbofans, turboprops, and turboshafts. Still other modifications which fall within the scope of the present invention will be apparent to those skilled in the art, in light of a review of this disclosure, and such modifications are intended to fall within the appended claims.
