The present invention generally relates to flow through a cased rotor, and more particularly relates to axially grooved rotor casings fabricated by advanced manufacturing techniques.
In rotary equipment such as fans, compressors and turbines, air flow past the rotating elements is influenced by the flow channel as defined by the casing structure surrounding the rotor. Rotor efficiency, and its impact on fuel consumption and performance, is influenced by the area near the rotor tips and the surrounding structure. Clearance around the rotor tips may be the source of significant losses. The rotor tip clearance losses may be magnified when the flowing gas does not follow its intended path and negatively impacts output due to interactions with the surrounding structure's boundary layer. For example, operating conditions may result in reduced surge margin and lower efficiency potential. Complex structures at the rotor-stator interface may improve performance but may be prohibitively difficult to fabricate using conventional manufacturing techniques.
Various types of articles may be created using additive manufacturing processes. Additive manufacture includes processes such as those that create a component or item by the successive addition of particles, layers or other groupings of a material onto one another. The article is generally built using a computer controlled machine based on a digital representation, and includes processes such as 3-D printing. A variety of different additive manufacturing processes are used such as processes that involve powder bed fusion, laser metal deposition, material jetting, or other methods.
It is desirable to create rotor systems using effective, efficient and economical manufacturing methods of rotor system parts. It is also desirable to manufacture rotor systems that have extended performance ranges and for handling increased aerodynamic loadings. Furthermore, other desirable features and characteristics of the present invention will become apparent from the subsequent detailed description of the invention and the appended claims, taken in conjunction with the accompanying drawings and this background of the invention.
This summary is provided to describe select concepts in a simplified form that are further described in the Detailed Description section hereof. This summary is not intended to identify key or essential features of the claimed subject matter, nor is it intended to be used as an aid in determining the scope of the claimed subject matter.
A number of embodiments include a method of manufacturing a rotor system that may employ additive manufacturing techniques to form complex geometries that result in improved performance. The method includes designing a casing with stall enhancement features. A rotor is fabricated with a number of blades with tips. The rotor is configured to rotate in a flow stream. The casing is constructed to fit over the rotor so that tips of the blades are configured to pass proximate the casing when the rotor rotates about an axis. The casing is formed by additive manufacturing with a series of grooves in the casing. The grooves extend into the casing radially outward relative to the axis and are oriented to extend longitudinally at an acute angle relative to the axis to provide stall enhancement. Aerodynamic performance of the grooves is optimized by analysis to avoid stall. The rotor is assembled in the casing with the grooves extending over at least a portion of the blade tips so that the blade tips are configured to pass across the grooves when the rotor rotates.
Other embodiments include rotor system that includes a rotor with blades that extend to tips. A casing fits over the rotor so that the tips are configured to pass proximate the casing when the rotor rotates. The casing is configured to channel a flow stream across the rotor and includes a section that is formed separate as a number of segments. The segments define a series of grooves that extend into the segments in a radially outward direction relative to the rotor's axis. The grooves are oriented to extend longitudinally at an acute angle relative to the axis. The grooves extend a distance upstream from a leading edge of the blades and over at least a portion of the blade tips so that the blade tips are configured to pass across the grooves when the rotor rotates.
In additional embodiments, a method of manufacturing a rotor system for an engine includes designing a casing with stall enhancement features. A rotor is fabricated with a number of blades. Each has a leading edge, a trailing edge and a tip. The rotor is configured to rotate in a flow stream of the engine. The casing is constructed to fit over the rotor so that blade tips of the rotor are configured to pass proximate a segmented section of the casing when the rotor rotates about an axis, and so that the casing channels the flow stream across the rotor. Size, orientation and shape of the grooves is determined to provide an aerodynamic performance that avoids stall and surge. The segmented section of the casing is formed by additive manufacturing. The segmented section includes the grooves that extend into the casing radially outward from the axis. The rotor is assembled in the segmented sections of the casing with the grooves extending a distance upstream from the blade tips beyond the leading edge and over at least a portion of the blade tips in the axial direction so that the blade tips are configured to pass across the grooves when the rotor rotates.
The present invention will hereinafter be described in conjunction with the following drawing figures, wherein like numerals denote like elements, and wherein:
The following detailed description is merely exemplary in nature and is not intended to limit the invention or the application and uses of the invention. As used herein, the word “exemplary” means “serving as an example, instance, or illustration.” Thus, any embodiment described herein as “exemplary” is not necessarily to be construed as preferred or advantageous over other embodiments. All of the embodiments described herein are exemplary embodiments provided to enable persons skilled in the art to make or use the invention and not to limit the scope of the invention which is defined by the claims. Furthermore, there is no intention to be bound by any expressed or implied theory presented in the preceding technical field, background, brief summary, or the following detailed description.
In the following description, features such as grooves, passages and channels may be created by using an additive manufacturing process such as direct metal laser sintering (DMLS) to extend the performance characteristics of a rotor system by enabling complex geometry at the rotor-stator interface. Axially oriented casing treatment approaches, including those with recirculation passageways are disclosed herein to provide beneficial performance characteristics. Additive manufacturing has been identified as an enabler for creating these complex parts, which otherwise may be prohibitively difficult to manufacture. In the examples given herein, details may be associated with a specific rotor and engine type, but the disclosure is not limited in application to any specific rotor or any particular type of engine but rather may be applied to any rotor where improved or extended performance is desired. In addition, the disclosure is not limited to any specific additive manufacturing process.
In embodiments of the present disclosure as further described below, systems, structures and methods of manufacturing relate to forming grooves and other features in a casing for a rotor, such as for an engine. Objectives include improving aerodynamic stall margin, efficiency and mechanical requirements. The casing or shroud is formed to fit over the rotor so that blade tips of the rotor are configured to pass proximate a section of the casing when the rotor rotates about an axis. The section may be formed is segments to facilitate manufacture. A series of grooves is formed in the segmented section of the casing. The grooves extend into the casing radially outward from the axis and are oriented such as to extend at angles relative to the axis. Aerodynamic performance as influenced by the grooves is optimized by evaluating alternative depths, orientations and shapes of the grooves to avoid stall and possible engine surge. The segmented sections of the casing may be fabricated by additive manufacturing with the grooves and other features incorporated. The rotor is assembled to rotate within the segmented sections of the casing with the grooves extending a distance upstream from the blade tips and over at least a portion of the blade tips so that the blade tips pass across the grooves when the rotor rotates.
The embodiments disclosed herein enable increased cycle pressure ratios and improved engine performance with higher aerodynamic loadings. Operational stability is extended at narrower surge margins. Stall in state of the art rotors may occur when system surge results in flow that leaks forward through the rotor's tip gap and causes local reverse flow. Reverse axial flow over the tip of a rotor (momentum flux), is a phenomenon associated with the onset of stall. This reverse flow is inhibited in the embodiments disclosed where grooves are employed to create resistance to the reverse flow over the rotor tip and allow the rotor to stably operate with significant increases in range from the operating line to stall. It has been found that additional benefits are realized when the grooves are generally axially oriented so that their longest dimension (length) is generally oriented in the axial direction. This axial orientation is made economically viable by the embodiments described herein, including by utilizing additive manufacturing processes.
As noted above, the grooved casing rotor systems and methods described herein may be employed in a variety of applications, including in a number of embodiments involving an engine. By way of an exemplary embodiment, an engine 22 will be described with reference to
The turbine section 42 includes one or more turbine stages. In the depicted embodiment, the turbine section 42 includes two turbine stages, a high-pressure turbine 58, and a power turbine 60. However, it will be appreciated that the engine 22 may be configured with a different number of turbine stages. As the turbines 58, 60 rotate, their rotors 46, 66 drive equipment in the engine 22 via concentrically disposed shafts or spools. Specifically, the high-pressure turbine rotor 46 drives the compressor rotor 68 via a high-pressure spool including the shaft 48, and the power turbine rotor 66 drives the fan rotor 70 via a low-pressure spool including the shaft 64. Clearance is provided between each of the rotors 46/66, 68, 70 and their respective casings 44, 72, 74 including to avoid blade incursions during rotation.
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The location, orientations and features of the grooves support these performance enhancements. More specifically, the location relative to the blades 80, the skewed and inclined dispositions and the shape each affect the improvements. Volumes of the grooves 92 are adjusted to control the frequency of the inflow/outflow to manage the rotor tip flow-field and to enhance range to stall. The grooves 92 are optimized, such as by modeling and through testing analysis. For example, aerodynamic performance of the grooves 92 is evaluated by testing alternative depths, widths, orientations and shapes of the grooves 92 to avoid compressor stall where flow may otherwise surge forward. For example, the grooves 92 may have curved or complex shapes.
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When the stall enhancement feature design meets aerodynamic stall margin, efficiency and mechanical requirements, the process 121 proceeds to integration/interfacing 123. The casing treatment with stall enhancement features is integrated into the engine's shroud around the rotor section including attachment features and segment interfaces. Manufacturability is balanced with a need to ensure the segments with casing treatment are securely contained. For example, interlocking structure may be used to prevent segment shifting, such as during surge. In addition, features may be formed by additive manufacturing to prevent leakage between the segments during engine operation.
The process 121 proceeds to defining 124 the specifics of the additive manufacturing process. For example, the type of additive manufacturing is selected. The current embodiment uses DMLS due to its applicability to forming complex geometries for parts with strength and durability. In addition, DMLS may be used to form the fine details of the casing treatment designs with high accuracy and quality. The build orientation of the segments is determined. The need for build supports and their structure is defined. Iterations of test builds may be carried out to choose a final orientation and support arrangement. The build arrangement is defined including determining whether segments will be manufactured individually or with several on a common build plate. Evaluations 125 are carried out to maximize weight reduction, manufacturing time and cost. For example, voids may be designed into the segments to reduce weight and material use. Test build iterations may be carried out to minimize support structure volume. Any potential for material collapse during build is evaluated.
The process 121 includes determining 126 whether weight or cost reductions may be made. For example, whether segment width or thickness may be reduced. When the determination is positive, the process 121 proceeds to evaluating redesign 128 of the stall enhancement features. For example, the size or orientation of grooves or passageways may be changed. The stall enhancement feature design is evaluated to ensure it meets aerodynamic stall margin, efficiency and mechanical requirements. When the redesign is complete, the process 121 proceeds through steps 123-126 again. Any number of iterations of steps 123-128 may be carried out to finalize the design. When the determination 126 is negative, the design is released 127 and manufacturing may begin. Providing an optimal shape and disposition of the grooves 92 is simplified through the use of additive manufacturing processes, which lowers manufacturing cost and fabrication complexity. In addition, using additive manufacturing processes enables forming the grooves with the shape that is determined to be optimized, including complex shapes.
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Through the embodiments disclosed herein increased performance is achieved with improved range to stall through the inclusion of generally axially extending grooves and/or recirculation passages. Forming the casing with the grooves is accomplished using an additive manufacturing process such as DMLS. While at least one exemplary embodiment has been presented in the foregoing detailed description, it should be appreciated that a vast number of variations exist. It should also be appreciated that the exemplary embodiment or exemplary embodiments are only examples, and are not intended to limit the scope, applicability, or configuration of the invention in any way. Rather, the foregoing detailed description will provide those skilled in the art with a convenient road map for implementing an exemplary embodiment of the invention. It being understood that various changes may be made in the function and arrangement of elements described in an exemplary embodiment without departing from the scope of the invention as set forth in the appended claims.