The field of the disclosure relates generally to jet pumps and, more particularly, to a jet pump having fully mixed flow in a distance less than four diameters of the mixing tube length.
At least some known aircraft air management systems (AMS) include supply sources for high-pressure (HP), low-pressure (LP), and mixed mode bleed levels. Typically, the HP and LP flows are supplied directly from a bleed port on a respective engine. Mixed mode bleed is supplied through a jet pump. The jet pump receives both HP and LP air flow, mixes the flows in selectable proportions and delivers the mixed mode bleed air to the AMS. Newer engines tend to have constrained space requirements that do not permit the use of standard architecture jet pump components and simply scaling the standard architecture jet pumps will not be able to mix the HP and LP flows adequately.
In one embodiment, a jet pump system includes a pre-mixing bowl that includes a nozzle along a central axis with a mixing section at least partially surrounding the nozzle. The pre-mixing bowl also includes a first inlet opening configured to receive a first flow of fluid from a first pressurized fluid source and direct the first flow of fluid to an inlet of the nozzle, a second inlet opening configured to receive a second flow of fluid from a second pressurized fluid source and to direct the second flow of fluid to the mixing section. The second inlet opening includes a first inlet opening area and an entry angle into the pre-mixing bowl that is oblique with respect to the central axis, and a third inlet opening configured to receive a third flow of fluid from the second pressurized fluid source and to direct the third flow of fluid to the mixing section. The third inlet opening including a second inlet opening area and an entry angle into the pre-mixing bowl that is oblique with respect to the central axis. The pre-mixing bowl also includes an outlet opening configured to direct the first, second and third flows of fluid from the pre-mixing bowl. The jet pump system further includes a mixing tube extending from the outlet opening aligned with the central axis.
In another embodiment, a method of supplying air at a plurality of different flows and a plurality of different pressures. The method includes channeling a first flow of relatively high pressure fluid to an inlet of a nozzle of a pre-mixer and channeling at least one of a plurality of flows of relatively low-pressure fluid and a second flow of relatively high-pressure fluid into a mixing section of the pre-mixer. The low pressure flows being of unequal flow rate and unequal flow velocity. The flows channeled through a respective arcuate path prior to entering the mixing section such that each of the plurality of flows of relatively low-pressure fluid has a flow gradient across the respective flows upon entry into the mixing section. The method also includes mixing the flow of relatively high-pressure fluid and the plurality of flows of relatively low-pressure fluid in the mixing section downstream of the nozzle as well as blocking the first flow of relatively high-pressure fluid to an inlet of a nozzle of the pre-mixer allowing the plurality of second flows of relatively lower pressure fluid into the mixing section such that only relatively low-pressure fluid enters the pre-mixer, and blocking the plurality of flows of relatively low-pressure fluid into the mixing section such that only the flow of relatively high-pressure fluid enters the pre-mixer.
In yet another embodiment, an aircraft includes an air management system (AMS) that includes a jet pump apparatus. The jet pump apparatus includes a pre-mixing bowl having a nozzle along a central axis, a pre-mixing section at least partially surrounding the nozzle, a first inlet opening configured to receive a first flow of fluid from a first pressurized fluid source and direct the first flow of fluid to an inlet of the nozzle, and a second inlet opening configured to receive a second flow of fluid from a second pressurized fluid source and to direct the second flow of fluid to the mixing section. The second inlet opening including a first inlet opening area and an entry angle into the pre-mixing bowl that is oblique with respect to the central axis. The pre-mixing bowl includes a third inlet opening configured to receive a third flow of fluid from the second pressurized fluid source and to direct the third flow of fluid to the mixing section. The third inlet opening including a second inlet opening area and an entry angle into the pre-mixing bowl that is oblique with respect to the central axis and an outlet opening configured to direct the first, second and third flows of fluid from the pre-mixing bowl. The jet pump apparatus further includes a mixing tube extending from the outlet opening aligned with the central axis.
These and other features, aspects, and advantages of the present disclosure will become better understood when the following detailed description is read with reference to the accompanying drawings in which like characters represent like parts throughout the drawings, wherein:
Unless otherwise indicated, the drawings provided herein are meant to illustrate features of embodiments of this disclosure. These features are believed to be applicable in a wide variety of systems comprising one or more embodiments of this disclosure. As such, the drawings are not meant to include all conventional features known by those of ordinary skill in the art to be required for the practice of the embodiments disclosed herein.
In the following specification and the claims, reference will be made to a number of terms, which shall be defined to have the following meanings.
The singular forms “a”, “an”, and “the” include plural references unless the context clearly dictates otherwise.
“Optional” or “optionally” means that the subsequently described event or circumstance may or may not occur, and that the description includes instances where the event occurs and instances where it does not.
Approximating language, as used herein throughout the specification and claims, may be applied to modify any quantitative representation that could permissibly vary without resulting in a change in the basic function to which it is related. Accordingly, a value modified by a term or terms, such as “about”, “approximately”, and “substantially”, are not to be limited to the precise value specified. In at least some instances, the approximating language may correspond to the precision of an instrument for measuring the value. Here and throughout the specification and claims, range limitations may be combined and/or interchanged, such ranges are identified and include all the sub-ranges contained therein unless context or language indicates otherwise.
The jet pump systems described herein provide a cost-effective method for providing mixed mode bleed air to an air management system (AMS) using a shorter length mixing tube than is currently available. Simply scaling down a standard architecture jet pump does not provide adequate mixing. The jet pump described herein is capable of having fully mixed flow in a distance less than four diameters of a length of a mixing tube portion of the jet pump. The embodiments described herein use high-pressure compressor (HPC) bleed from a fourth stage, relatively low-pressure port and/or tenth stage, relatively high-pressure port of a gas turbine engine compressor for the aircraft environmental control system (ECS) and Wing Anti-Ice (WAI). In the example embodiment, bleed from the fourth stage can be up to approximately 10% of core air flow and up to approximately 15% of core air flow from the tenth stage. Under certain conditions neither stage can deliver a required air pressure wherein the fourth stage operates below a first pressure/temperature limit and the tenth stage operates above a second pressure/temperature limit. Mixing the fourth stage and tenth stage bleed air is used to supply air between the capabilities that the fourth stage and tenth stage bleed air can supply alone. Specifically, the embodiments described herein use one or more of the following features to provide fully developed mixed flow in less than four diameters of the mixing section entrance. Namely, the features include upstream duct bends that promote non-uniform flow field between the multiple inlets and promote swirl in the flow of low-pressure air, without use of swirl vanes. Multiple low-pressure inlets of different diameters (but close to 50-50 flow split) allow the higher velocity LP leg to pre-swirl the lower velocity LP leg prior to HP flow introduction (i.e. preboost LP flow and produce better swirl in mixing duct), and multi-inlets arranged at an angle to mixed flow direction to balance swirl with flow performance requirements (minimize losses in LP stream). The feature also include a pre-mixing bowl to minimize total pressure losses and promote efficient swirl generation, pre-swirl to facilitate maintaining HP center jet coherence at mixing section entrance, allowing a shorter central nozzle, which is lighter weight, increases effective mixing length, lessens LP losses, and improves backflow margin. The features of the disclosed jet pump system further include a conic central nozzle that improves swirl generation by inducing the non-uniform inlet flow fields to flow around a central blockage in the mixing section downstream of the nozzle outlet, an HP nozzle is designed to maximize flow shear between the LP and the HP flow using a nozzle having lobes of various configurations, which approximates a compact and lightweight multi-port nozzle. The helix-lobed nozzle configuration generates additional HP swirl and additional mixing effectiveness in a relatively shorter mixing section than previous designs. The helix-lobed nozzle further provides additional LP swirl at the same time. The jet pump system described herein operates efficiently across the entire range of engine power levels, and across a broad range of LP/HP pressure ratios, which enables an HP pressure regulation strategy directed toward engine or jet pump efficiency, depending on which benefit is desired at al time.
A jet pump shutoff valve (JPSOV) 208 modulates to supply high-pressure air to a throat 210 of jet pump 205. A high-pressure shutoff valve (HPSOV) 212 modulates to supply high-pressure air from 10th stage ports 202 to a first inlet 214. Check valves 216 and 218 prevent back flow from 10th stage ports 202 to 4th stage bleed ports 204.
AMS supply source 200 operates in three modes where outlet 207 is supplied from low-pressure 4th stage bleed ports 204, from high-pressure bleed ports 202, and a mixed supply from both low-pressure 4th stage bleed ports 204 and high-pressure bleed ports 202. In a first mode, outlet 207 is supplied from low-pressure 4th stage bleed ports 204 with both JPSOV 208 and HPSOV 212 in a closed position. In a second mode, outlet 207 is supplied from high-pressure bleed ports 202 with JPSOV 208 in a closed position and HPSOV 212 in an open position. A third mode is a jet pump mode where HPSOV 212 is in a closed position and JPSOV 208 is in an open position. When in the open position, JPSOV 208 modulates to adjust flow from a single leg of the high-pressure supply portion 220 of AMS supply source 200.
A flow sensor is configured to measure an amount of the extracted flow from the 10th stage is going to AMS supply source 200. The 10th stage bleed measurement is used to maintain an operation of engine 106 according to a predetermined air management schedule. Bleeding air from the 10th stage may affect other stages of engine 106. A map of a range of 10th stage flow rates is used to determine an impact for the various flow rates on engine 106. The 10th stage bleed flow rate is accounted for in thrust schemes and fielding schemes that affect a performance of engine 106.
Pre-mixing bowl 1304 also includes a second inlet opening 1318 configured to receive a second flow of fluid 1320 from a second pressurized fluid source (not shown) and to direct second flow of fluid 1320 into mixing section 1310. Second inlet opening 1318 includes a first inlet opening area 1322 and is oriented with an entry angle 1324 into pre-mixing bowl 1304 that is oblique with respect to central axis 1308.
A third inlet opening 1326 is configured to receive a third flow of fluid 1328 from the second pressurized fluid source (not shown) and to direct third flow of fluid 1328 to mixing section 1310. Third inlet opening 1326 includes a second inlet opening area 1330 and an entry angle 1332 into pre-mixing bowl 1304 that is oblique with respect to central axis 1308. An outlet opening 1334 is configured to direct first flow, second flow 1320 and third flow 1328 from pre-mixing bowl 1304 into a mixing tube 1336 extending from outlet opening 1334 aligned with central axis 1308. Because of the different diameters or different areas of the inlet openings for the legs of the low-pressure flows and because the openings are oriented at angle that directs the flow towards the outlet, and because of the non-uniform flow gradient across the inlet openings generated by the predetermined bends of the inlet piping, the two low-pressure flows interact in a pre-swirl flow in pre-mixing bowl 1304 that facilitates maintaining a coherence at the HP center jet at the mixing section entrance, allowing a shorter central nozzle. Such a configuration permits a lighter weight jet pump having an increased effective mixing length with less losses associated with the LP flow and an improved backflow margin. Conic central nozzle 1306 improves swirl generation by inducing non-uniform inlet low-pressure flow fields to flow around the central blockage of the mixing section. Nozzle 1306 is also configured to maximize a flow shear between LP and HP flow using a lobed configuration, which approximates a compact and lightweight multi-port ejector. In various embodiments, other nozzle shapes and designs can meet the same objective. The helix lobed configuration also generates additional HP swirl and additional mixing effectiveness in an even shorter mixing section and generates additional LP swirl at the same time. The jet pump system describe herein operates efficiently across the entire range of engine power levels, and across a broad range of LP/HP pressure ratios.
Although specific features of various embodiments of the disclosure may be shown in some drawings and not in others, this is for convenience only. In accordance with the principles of the disclosure, any feature of a drawing may be referenced and/or claimed in combination with any feature of any other drawing.
This written description uses examples to disclose the embodiments, including the best mode, and also to enable any person skilled in the art to practice the embodiments, including making and using any devices or systems and performing any incorporated methods. The patentable scope of the disclosure is defined by the claims, and may include other examples that occur to those skilled in the art. Such other examples are intended to be within the scope of the claims if they have structural elements that do not differ from the literal language of the claims, or if they include equivalent structural elements with insubstantial differences from the literal language of the claims.
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