The disclosure relates to improved designs for engine components that include at least one internal fluid annular passage formed in a sandwich structure within an engine casing. The disclosure provides structure optimized to provide for one or more of the following characteristics: structural integrity, thermo-mechanical load carrying capability, buckling, containment, cooling and/or temperature control, flow pressure drop, improved temperature gradient and finally improved life of component.
Gas turbine engines generally include at least one compressor and at least one turbine section each having rotating blades contained within an engine housing. One of the goals in designing an engine housing is to maintain a lightweight structure while still providing enough strength to contain any rotating blade that may break (i.e. blade containment). Because any broken blades must be contained within the housing, the walls of engine housings must be manufactured to ensure broken blades do not puncture the housing. Proposals to reduce weight and strengthen the turbine case have relied on additive manufacturing techniques to prepare a sandwich structure for the case with an intermediate layer that is a porous structure and/or honeycomb structure. See U.S. Pat. Appl'n. Pub. No. 2014/0161601. These designs provide an internal porous or honeycomb structure between the inner and outer walls of an engine casing, which is designed to increase strength while reducing the weight of the engine casing. These designs primarily rely on external piping to cool the composite engine casing.
Turbine engines may also incorporate active clearance control (ACC) to help maintain proper temperature of the engine casing and provide proper rotor/case clearance during a range of operating conditions and parameters. For Example, ACC may be used to control the case diameter to increase and conform to expected blade growth or decrease in diameter for blade contraction under various engine operating conditions. Impingement cooling is frequently employed in ACC systems to control the temperature of the engine casing. Impingement cooling generally relies on the formation of a boundary layer on the surface of the component, for example. Frequently in an ACC system, an external pipe arrangement may be employed to supply cooler air to the surfaces of the engine case. As shown in
Through the use of additive manufacturing techniques, an engine casing may be formed having an internal cooling circuit. The internal cooling circuit, may be used, along with other benefits, to control the temperature of the engine case and/or deliver required cavity purge air. Through control of the engine case temperature using the internal cooling circuit, ACC control may be possible without the additional weight and complexity of an external ACC system. Additional advantages and novel features of these aspects will be set forth in part in the description that follows, and in part will become more apparent to those skilled in the art upon examination of the following or upon learning by practice of the disclosure.
The accompanying drawings, which are incorporated into and constitute a part of this specification, illustrate one or more example aspects of the present disclosure and, together with the detailed description, serve to explain their principles and implementations.
Typically, turbine includes a compressor portion, a combustion portion, and a turbine portion. The turbine portion may include a gas generator turbine (GT) and a power turbine (PT). While the majority of the description below describes the power turbine (PT) portion of a turbine, the present invention is applicable to the compressor portion of the turbine as well. The following detailed description sets forth an internal annular cavity for providing temperature control to a power turbine (PT) by way of example and not by way of limitation. For example, the disclosed aspects may be implemented in other engine parts for case cooling and/or temperature control for other parts such as a high pressure turbine (HPT) or low pressure turbine (LPT), the high pressure compressor (HPC) or low pressure compressor (LPC), turbine center frame (TCF), and combustor, for example. The description should clearly enable one of ordinary skill in the art to make and use the internal annular cavity, and the description sets forth several aspects, adaptations, variations, alternatives, and uses of the internal passage, by way of example. The internal fluid cavity described herein as being applied to a few preferred aspects, namely to different embodiments of the internal cooling passages for an PT engine case. However, it is contemplated that the internal cooling passages and method of fabricating the internal annular cavity may have general application in a broad range of systems and/or a variety of commercial, industrial, and/or consumer applications other than the internal temperature control for a PT case of a turbine engine.
The turbine casing 200 may comprise a series of casing rings that are joined to form a single casing defining an inner chamber surrounding the turbine assembly, or the turbine casing may be comprised of a single uninterrupted structure forming a chamber. The power turbine may include an array of stator vanes 18, which may be attached at a radially outward end to the inner part of the turbine casing. The stator vanes 18 may be either formed as a single structure with the turbine casing 200 or may be attached to the casing using bolts or studs (not shown). Sealing portions 228 may be attached to the casing 200 through brazing, may be press fit, may be attached using fasteners commonly known and used in the art, and/or may include a single or plurality of attachment portions 231 that fit into corresponding attachment portion receiving sections 230 on the casing 200. Each blade 212 may include at least one tip shroud 214 to improve clearance between the sealing portion 228 and the blade 212 and/or to suppress resonant vibration. During operation, the turbine blades 212 and/or stator vanes 18 may experience growth or contraction due to thermal effects on the metals and/or may experience due to rotational forces. As an example, any space between blades 212 and sealing portions 228 results in a leakage of gasses, and accordingly, a loss in energy. Further, an increase in the abovementioned clearance allows more bypass flow around the blade tips and seals which may also introduce a mixing loss when it re-enters the flow path at a location 240 of the chamber downstream of the seal. If too little space is maintained between the blades 212 and the sealing portion 228 contact and binding may occur during operation. Accordingly, clearance between blades of the turbine and the seals and/or casing may have a strong impact on performance. Several example explanations of the changes in part dimensions in a turbine due to various operating conditions, and parameters for controlling the temperature of the casing to correspond to the abovementioned conditions are explained in U.S. Pat. No. 5,012,420 A, which is hereby incorporated by reference.
The turbine casing may be manufactured using an additive manufacturing (AM) technique, which may include selective laser sintering (SLS), direct metal laser sintering (DMLS) and three dimensional printing (3DP). Any of the above additive manufacturing techniques may be used to form the turbine casing from stainless steel, aluminum, titanium, Inconel 625, Inconel 718, cobalt chrome, among other metal materials or any alloy thereof. In each of the abovementioned additive manufacturing techniques powder based fabrication methods, powdered material may be melted or sintered to form each part layer. For example, the additive manufacture of large parts having integrated cooling can be accomplished using an apparatus and method such as described below.
The apparatus 110 is controlled by a computer executing a control program. For example, the apparatus 110 includes a processor (e.g., a microprocessor) executing firmware, an operating system, or other software that provides an interface between the apparatus 110 and an operator. The computer receives, as input, a three dimensional model of the object to be formed. For example, the three dimensional model is generated using a computer aided design (CAD) program. The computer analyzes the model and proposes a tool path for each object within the model. The operator may define or adjust various parameters of the scan pattern such as power, speed, and spacing, but generally does not program the tool path directly.
In one aspect, the active clearance control (ACC) flow 250 may be routed in between two layers, which may comprise an annular outer layer 200 and an inner annular layer 226 and flow cavity 225 through which fluid may flow between the two layers. The annular outer layer 200 and inner layer 226 having an inner wall 211 may be connected through the flow cavity 225 by an internal lattice structure (not shown) or a pin bank comprising a plurality of pins 220 connecting the annular outer layer 200 and the inner annular layer 226. Any of the above additive manufacturing techniques may be utilized to form the annular outer layer, the annular inner layer and the pin bank as a single uninterrupted structure. The pin bank may include a series of pin banks. The pin banks may further be connected to the outer annular layer 200 and inner annular layer 226 to maintain a heat conduction path for outer and/or inner case cooling and/or to control the clearance between the turbine blades 212 and seal portions 228 and/or to control the clearance between the stator veins 210 and the stator seal (not shown). The pin banks be dimensioned and arranged to further promote heat transfer and allow for impingement cooling of the outer annular layer to cool the inner annular layer. The pin banks may further be arranged to carry any required structural loads between the outer and inner layer.
In one aspect, the pins 220 connect the outer annular layer 200 and the inner annular layer 226 at a portion of the inner annular layer where the vanes 212 and/or seal portions 228 are mounted, such an arrangement of the pins 220 may ensure any external case impingement cooling remains effective in the event that ACC system is turned off or is not functioning. As shown in
Allowing controlled flow of fluid to travel between the outer layer 200 and inner layer 226 in the flow cavity 225 allows for replacing at least a portion of an existing solid case with external ACC pipe arrangement with the abovementioned case having multiple layers. In one aspect, the external pipes used to cool the solid case in a LPT engine are partially or entirely replaced through the use of internal annular cavity 225 in the case. In one arrangement, the ACC fluid flow may be combined with higher pressure air from the secondary air system (SAS) in order to achieve the cooling and clearance objectives of the system. The particular coolant path and pin bank, turbulation features, and/or serpentine flow path structure may be designed to account for the pressure drop in the system and to optimize the SAS. As shown in
The air inlet 222 may be connected to at least one valve (not shown) which may be connected to a bay air source or other auxiliary fluid source. The valve may be a modulation valve connected to a single air source (e.g. bay air) to control the flow of fluid and/or the temperature of the fluid in the flow cavity based on various detected operating parameters and the flow rate and temperature of the fluid, and heat transfer from the materials known to cause an optimal clearance between the inner annular layer 226 of the case and the veins 220 and/or blades 212. The valve may also comprise at least one modulating and at least one mixing valve, that may vary the proportions of fluid from multiple sources. Further, in one aspect, the upstream cavity opening may be open to a bay air source and/or the valve may default to or remain open when an the ACC system is not in use or in case the ACC system fails; the ejection flow path through outlet 232 in fluid communication with the flow cavity and the PT cause a positive flow (e.g. from the upstream air inlet 222 to the downstream ejection flow path outlet 232) to assure that fluid flows through the flow cavity at all times to provide for proper cooling of the PT case. The downstream outlet 232 may include at least one ejector 242. The ejectors may have an exit in the main air stream flow path CF, which may create a pressure differential due to a venturi effect. The pressure differential may ensure a positive pressure gradient always exists across the flow cavity. The ejector 242 may also be a trumpet shaped ejector. The abovementioned ejectors 242 may be formed by any one of the abovementioned additive manufacturing techniques and may be installed separately on at least one of the outlet 232 or may be formed as a unitary structure with at least one of the outlet 232 though the abovementioned additive manufacturing techniques, for example.
Through the abovementioned control of the fluid traveling in the flow cavity 225 the temperature of inner annular layer 226 may be raised or lowered by up to 100° By raising or lowering the temperature of the inner annular layer 226, proper clearances between the tip shrouds 214 and seal portions 228 and/or the stator veins 210 and stator seals (not shown) may be maintained. The abovementioned control of proper clearances may be especially advantageous for rotorcraft capable of flight speeds greater than 200 knots.
While the aspects described herein have been described in conjunction with the example aspects outlined above, various alternatives, modifications, variations, improvements, and/or substantial equivalents, whether known or that are or may be presently unforeseen, may become apparent to those having at least ordinary skill in the art. Accordingly, the example aspects, as set forth above, are intended to be illustrative, not limiting. Various changes may be made without departing from the spirit and scope of the disclosure. Therefore, the disclosure is intended to embrace all known or later-developed alternatives, modifications, variations, improvements, and/or substantial equivalents.