The present disclosure relates generally to a turbine connector for an engine exhaust manifold, and more particularly to a turbine foot shaped to resist cracking, facilitate installation, and optimize exhaust flow to a turbine in an exhaust system.
Many modern internal combustion engines employ one or more turbochargers to extract energy from engine exhaust and use the energy to increase a pressure of intake air. In a typical configuration a turbocharger is mounted to an engine exhaust manifold which collects flows of exhaust from combustion cylinders in the engine and feeds combined flows of the exhaust to an inlet of a turbine in the turbocharger. The flow of exhaust through the turbine impinges upon vanes of the turbine inducing the turbine to rotate. A shaft of the turbine extends to a compressor wheel positioned fluidly in an incoming flow of intake air for the engine or sometimes intake air and fumigated fuel and/or recirculated exhaust. Rotation of the compressor wheel increases a pressure of the intake air enabling the associated internal combustion engine to operate with an increased power, increased power density, and/or improved efficiency based on the extraction of exhaust energy that would otherwise be wasted.
The operating environment of a typical turbocharger is quite harsh as the turbocharger itself as well as associated components can be subjected to extreme temperatures, temperature swings, high absolute pressures, corrosive fluids, and an overall dynamic mechanical environment. For these reasons, turbochargers, exhaust manifolds, and associated equipment are commonly built to be quite robust. As noted above, an engine exhaust manifold generally collects the exhaust from multiple cylinders and provides a feed of combined flows of exhaust to the turbocharger. A desire to limit disruption, perturbation, or so-called “cross-talk” in exhaust flows caused by the dynamic and rapidly changing pressures cylinder-to-cylinder has led many manufacturers to design the exhaust feed to the turbine in a manner where the exhaust flows from some of the cylinders are divided from exhaust flows from other cylinders at least up to the point at which the exhaust enters the turbine housing. Such a construction requires a dividing wall or web separating exhaust flows at the point where the exhaust flows exit the exhaust manifold and enter the turbine housing. Relatively thin metal dividing walls in exhaust manifold castings can experience stress and potentially thermal fatigue earlier in the service life of an engine than desired. One known exhaust system having a low-stress exhaust manifold flange is set forth in U.S. Pat. No. 6,892,532 to Bruce et al. Bruce et al. propose an exhaust system where an exhaust flange is connected to an exhaust manifold, and a turbocharger connected to the exhaust flange. The turbocharger has an exhaust inlet flange connected to the exhaust flange. Exhaust ports of the exhaust flange each have a generally triangular cross-sectional configuration.
In one aspect, a turbine connector for an engine exhaust manifold includes a first incoming exhaust conduit and a second incoming exhaust conduit. The turbine connector further includes a turbine foot attached to the first incoming exhaust conduit and to the second incoming exhaust conduit. The turbine foot includes an engine-facing side, and a turbine-mounting side opposite to the engine-facing side and including a land defining a turbine-mounting plane. The turbine foot further includes an outer edge having a long perimetric base, a short perimetric base, and a first perimetric leg and a second perimetric leg each extending angularly between the long perimetric base and the short perimetric base. The turbine foot further includes a first inner edge forming a first exhaust outlet from the first incoming exhaust conduit opening in the land, a second inner edge forming a second exhaust outlet from the second incoming exhaust conduit opening in the land, and a web extending between the first exhaust outlet and the second exhaust outlet. The first inner edge and the second inner edge each have a varied perimetric curvature that is largest in finite curvature size upon the web, and together forming an hourglass web profile in the turbine-mounting plane.
In another aspect, an engine exhaust manifold includes a first exhaust pipe structured to fluidly connect to a first set of engine cylinders, and a second exhaust pipe structured to fluidly connect to a second set of engine cylinders. The engine exhaust manifold further includes a turbine connector coupled to the first exhaust pipe and to the second exhaust pipe and including a turbine foot. The turbine foot has an outer perimetric edge defining a trapezoidal shape, a first inner perimetric edge, and a second inner perimetric edge. The first inner perimetric edge forms a first exhaust outlet for feeding exhaust from the first set of engine cylinders to a turbine, and the second inner perimetric edge forms a second exhaust outlet for feeding exhaust from the second set of engine cylinders to the turbine. The turbine foot further includes a web extending between the first exhaust outlet and the second exhaust outlet. The first exhaust outlet and the second exhaust outlet are mirror images of one another, and each has a varied inside curvature that is largest in finite curvature size upon the web.
In still another aspect, a turbine connector for an engine exhaust manifold includes a first incoming exhaust conduit and a second incoming exhaust conduit. The turbine connector further includes a turbine foot attached to the first incoming exhaust conduit and to the second incoming exhaust conduit, and having an engine-facing side, and a turbine-mounting side opposite to the engine-facing side and including a land defining a turbine-mounting plane. The turbine foot further includes an outer edge defining a trapezoidal shape, and having therein a plurality of bolt holes extending between the engine-facing side and the turbine-mounting side and arranged in a trapezoidal pattern congruent with the trapezoidal shape. The turbine foot further includes a first inner edge forming a first exhaust outlet from the first incoming exhaust conduit opening in the land, a second inner edge forming a second exhaust outlet from the second incoming exhaust conduit opening in the land, and a web extending between the first exhaust outlet and the second exhaust outlet. The first inner edge and the second inner edge each have a varied perimetric curvature and together form an hourglass web profile in the turbine-mounting plane.
Referring to
Internal combustion engine system 10 further includes an exhaust system 20 including a turbocharger 22 having a turbine 24 and a turbine inlet 26. Exhaust system 20 also includes an engine exhaust manifold 30 structured to collect exhaust from a plurality of combustion cylinders formed in cylinder block 12. In a practical implementation, exhaust system 20 may further include aftertreatment apparatus (not shown) structured to receive a flow of exhaust from turbine 24 and treat the exhaust to reduce certain emissions in a generally conventional manner. An intake manifold is shown at 28 and is structured to receive a flow of intake air for feeding to the respective combustion cylinders from a compressor (not shown) of turbocharger 22.
Referring also now to
In the illustration of
Turbine connector 40 further includes a turbine foot 54 attached to first incoming exhaust conduit 42 and to second incoming exhaust conduit 46. Turbine foot 54 includes an engine-facing side 56, and a turbine-mounting side 58 opposite to engine-facing side 56 and including a land 60 defining a turbine-mounting plane 62. In a practical implementation, a gasket, one or more metallic seal, or similar element(s) is sandwiched between turbine foot 54 and turbocharger 22 when turbocharger 22 is installed for service in internal combustion engine system 10.
Turbine foot 54 further includes a continuous outer perimetric edge 72 (hereinafter “outer edge 72”). Outer edge 72 has a long perimetric base 74, a short perimetric base 76, and a first perimetric leg 78 and a second perimetric leg 80 each extending angularly between long perimetric base 74 and short perimetric base 76. It can be seen that in the illustrated embodiment long perimetric base 74, short perimetric base 76, first perimetric leg 78, and second perimetric leg 80, together define a trapezoidal shape. Also in the illustrated embodiment, the trapezoidal shape is an isosceles trapezoid. A trapezoidal shape, or other shapes where perimetric legs extend angularly between a long base and a short base, can provide for an optimized size, land area, and flow area for exhaust as further discussed herein, and can assist in assembly operations of internal combustion engine system 10.
Referring also now to
Turbine foot 54 still further includes a web 94 extending between first exhaust outlet 88 and second exhaust outlet 92, dividing turbine foot 54, and separating flows of exhaust from respective sets of combustion cylinders that are fed into turbine inlet 26 of turbocharger 22. First inner edge 86 and second inner edge 90 each have a varied perimetric curvature that is largest in finite curvature size upon web 94. Largest in finite curvature refers to the curvatures that are largest, relative to other curvatures of inner edges 86 and 90, and not infinite as might be defined by a linear or substantially linear edge segment. Stated another way nowhere is a finite curvature of inner edges 86 and 90 larger than upon web 94.
First inner edge 86 and second inner edge 90 together form an hourglass web profile in turbine mounting plane 62. It will be understood that turbine-mounting plane 62 is a plane of the page in
Each of first inner edge 86 and second inner edge 90 may include a curved perimeter segment 96 and 98, respectively, upon web 94, and having the largest finite curvature noted above, at least in turbine-mounting plane 62. Each curved perimeter segment 96 and 98 may also thus form a circular arc segment. Each of first inner edge 88 and second inner edge 90 may further include a linear perimeter segment 100 and 102, respectively, opposite to the respective curved perimeter segments 96 and 98 and oriented parallel to an adjacent one of first perimetric leg 78 and second perimetric leg 80. Each of first inner edge 86 and second inner edge 90 may further include another linear perimeter segment 104 and 106, respectively, adjacent to long perimetric base 74, and still another linear perimeter segment 108 and 110, respectively, adjacent to short perimetric base 76.
With continued reference to
To this end, a ratio of the radius size dimension defined by radius 126 to long-span dimension 114 may be less than 32% or 0.32:1, and a ratio of the subject radius size dimension to short-span dimension 118 may be greater than 32% or 0.32:1. In a refinement, the ratio of the subject radius size dimension to long-span dimension 114 may be about 28% or 0.28:1, and the ratio of the subject radius size dimension to short-span dimension 118 may be about 36% or 0.36:1. A ratio of short-span dimension 118 to long-span dimension 114 may be from 75% or 0.75:1 to 80% or 0.80:1, and in a refinement may be from about 77% or 0.77:1 to about 78% or 0:78:1. Also in a practical implementation, first exhaust outlet 88 and second exhaust outlet 92 together define a flow area, land 60 also defines a land area, and a ratio of the flow area to the land area may be from 44% or 0.44:1 to 54% or 0.54:1. In a refinement the ratio of the flow area to the land area may be from about 48% or 0.48:1 to about 50% or 0.50:1. As used herein the term “about” can be understood in the context of conventional rounding to a consistent number of significant digits. Accordingly, “about 0.48” means from 0.475 to 0.484, and so on.
As discussed above, the general shape formed by turbine foot 54, which may be an isosceles trapezoid shape, for example, can assist in assembly and installation of turbocharger 22 in exhaust system 20, and also provides a relatively large land area within which exhaust outlet areas can be made relatively large without requiring outside walls of turbine foot 54 or web 94 to be made unduly thin or sharply radiused to the point of promoting thermal-fatigue cracking or causing other problems. The inner peripheral shapes and proportional attributes of inner edge 86 and inner edge 90 can thus be understood to provide optimized shape and flow area in conjunction with the outer peripheral shape of turbine foot 54 itself. Put differently, exhaust outlets 88 and 92 provide an optimized flow area that fits within a trapezoidal or similar shape while still providing a web thickness and size and wall thicknesses sufficient to be relatively crack-resistant in response to thermal cycling or the like over the course of an engine service life or service interval. The hourglass divider wall as disclosed herein, and other geometric and proportional attributes thus provide robustness and optimized flow area to the inlet assembly on the exhaust manifold side, while the trapezoidal or otherwise analogously shaped foot facilitates easy assembly and installation of the exhaust manifold and turbine, ultimately reducing overall production time.
The present description is for illustrative purposes only, and should not be construed to narrow the breadth of the present disclosure in any way. Thus, those skilled in the art will appreciate that various modifications might be made to the presently disclosed embodiments without departing from the full and fair scope and spirit of the present disclosure. Other aspects, features and advantages will be apparent upon an examination of the attached drawings and appended claims. As used herein, the articles “a” and “an” are intended to include one or more items, and may be used interchangeably with “one or more.” Where only one item is intended, the term “one” or similar language is used. Also, as used herein, the terms “has,” “have,” “having,” or the like are intended to be open-ended terms. Further, the phrase “based on” is intended to mean “based, at least in part, on” unless explicitly stated otherwise.
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Written Opinion and International Search Report for Int'l. Patent Appln. No. PCT/US2021/055494, dated Feb. 4, 2022 (16 pgs). |
Number | Date | Country | |
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20220162978 A1 | May 2022 | US |