This application claims priority to Japanese Patent Application No. 2016-159269 filed on Aug. 15, 2016, which is incorporated herein by reference in its entirety.
This disclosure relates to an intake manifold for a V-type internal combustion engine.
As described in Japanese Patent Application Publication No. 2010-014018 (JP 2010-014018 A), in a V-type internal combustion engine, an intake manifold is provided between a first cylinder head an a first bank side and a second cylinder head on a second bank side. Intake air from outside is supplied from the intake manifold to an intake port of the first cylinder head and an intake port of the second cylinder head. Further, the intake manifold includes: an upstream portion including a first upstream passage and a second upstream passage into which the intake air from outside is introduced; a first downstream portion including a first downstream passage configured to communicate the first upstream passage with the intake port of the first cylinder head; and a second downstream portion including a second downstream passage configured to communicate the second upstream passage with the intake port of the second cylinder head. In the first downstream portion, a downstream end of the first downstream passage is connected to the first cylinder head. In the second downstream portion, a downstream end of the second downstream passage is connected to the second cylinder head. In the intake manifold described in JP 2010-014018 A, the upstream portion, the first downstream portion, and the second downstream portion are formed integrally so as to form a shape extending from the first cylinder to the second cylinder head as a whole.
Upon receipt of heat caused due to combustion of a fuel/air mixture in a combustion chamber of the internal combustion engine, the internal combustion engine thermally expands outward so that the first cylinder head and the second cylinder head are displaced in directions to be distanced from each other. Note that, at this time, the intake manifold also thermally expands, but an extent a the thermal expansion of the cylinder head or the cylinder block closer to the combustion chamber in terms of distance is larger than that of the intake manifold. On this account, in the intake manifold described in JP 2010-014018 A, when such a thermal expansion occurs, the first downstream portion and the second downstream portion are pulled so as to be distanced from each other via their respective connection portions with the cylinder heads. When such a force acts, a stress is applied to the respective connection portions with the cylinder heads in the first downstream portion and the second downstream portion of the intake manifold. Accordingly, the connection portions with the first downstream portion and the second downstream portion are displaced, so that sealing characteristics of the connection portions might decrease.
The present disclosure has been accomplished in consideration of the above-mentioned circumstances, and intends to restrain a decrease in a sealing characteristic of a connection portion of a downstream portion of an intake manifold with a cylinder head, the decrease in the sealing characteristic being caused due to thermal expansion of an internal combustion engine.
In view of this, one aspect of the present disclosure provides an intake manifold for an internal combustion engine, the intake manifold including an upstream portion, a first downstream portion, and a second downstream portion. The internal combustion engine includes a first cylinder on a first bank side and a second cylinder on a second bank side, and the first cylinder and the second cylinder are inclined so as to approach each other toward a side closer to a crankshaft. The intake manifold is provided between a first cylinder head on a first bank side and a second cylinder head on a second bank side in the internal combustion engine. The intake manifold is configured to supply intake air from outside to an intake port of the first cylinder head and an intake port of the second cylinder head. The upstream portion of the intake manifold includes a first upstream passage and a second upstream passage into which the intake air from outside is introduced. The first downstream portion includes a first downstream passage configured to communicate the first upstream passage with an intake port of the first cylinder head. The second downstream portion includes a second downstream passage configured to communicate the second upstream passage with an intake port of the second cylinder head. Further, (i) the upstream portion, the first downstream portion, and the second downstream portion are provided separately, (ii) an upstream end of the first downstream portion is connected to a first downstream end of the upstream portion, and the first upstream passage is opened in the first downstream end, and (iii) an upstream end of the second downstream portion is connected to a second downstream end of the upstream portion, and the second upstream passage is opened in the second downstream end.
With the configuration of the intake manifold, when the internal combustion engine thermally expands and the cylinder heads are distanced from each other, not only a positional displacement in a connection portion between the downstream end of the first downstream portion and the first cylinder head, but also a positional displacement in a connection portion between the upstream end of the first downstream portion and the downstream end of the upstream portion might occur. By dispersing the parts where a positional displacement occurs as such, it is possible to reduce a degree of the positional displacement in the downstream end of the first downstream portion. Accordingly, it is possible to restrain an excessive positional displacement that might decrease a sealing characteristic in the downstream end of the first downstream portion. The same can be said about the second downstream portion.
Further, in the intake manifold, the upstream portion is formed by a gravity casting process, and the first downstream portion and the second downstream portion are formed by die casting. With such an intake manifold, it is possible to reduce thicknesses of respective side wails of the first downstream passage and the second downstream passage in the internal combustion engine, thereby making it possible to achieve a weight reduction of the intake manifold.
Further, in the intake manifold, the upstream portion is formed by die casting, and the first downstream portion and the second downstream portion are formed by gravity casting. With such an intake manifold, it is possible to reduce thicknesses of respective side walls of the first downstream passage and the second downstream passage in the internal combustion engine, thereby making it possible to achieve a weight reduction of the intake manifold.
Features, advantages, and technical and industrial significance of exemplary embodiments of the disclosure will be described below with reference to the accompanying drawings, in which like numerals denote like elements, and wherein:
An embodiment as an example of an intake manifold for an internal combustion engine is described below with reference to
As illustrated in
Inside the cylinder 15L on the first bank side, a piston 13L is provided so as to reciprocate in the cylinder 15L. Similarly, inside the cylinder 15R on the second bank side, a piston 13R is provided so as to reciprocate in the cylinder 15R. The pistons 13L, 13R are connected to the crankshaft 40, so that the crankshaft 40 rotates along with the reciprocations of the pistons 13L, 13R.
A first cylinder head 16L is fixed to the cylinder block 14 so as to correspond to the cylinders 15L on the first bank side. Further, a second cylinder head 16R is fixed to the cylinder block 14 so as to correspond to the cylinders 15R on the second bank side.
The first cylinder head 16L is provided with an intake port 17L configured to supply intake air to a combustion chamber of the cylinder 15L of the cylinder block 14, and an exhaust port 18L configured to discharge exhaust gas from the combustion chamber of the cylinder 15L. The intake port 17L is opened in a part of the first cylinder head 16L on a side closer to the second cylinder head 16R than a center of the first cylinder head 16L. Further, the intake port 17L is provided with a fuel injection valve 19L configured to inject and supply fuel into the intake port l7L.
Further, the second cylinder head 16R is provided with an intake port 17R configured to supply the intake air to a combustion chamber of the cylinder 15R of the cylinder block 14, and an exhaust port 18R configured to discharge exhaust gas from the combustion chamber of the cylinder 15R. The intake port 17R is opened in a part of the second cylinder head 16R on a side closer to the first cylinder head 16L than a center of the second cylinder head 16R. Further, the intake port 17R is provided with a fuel injection valve 19R configured to inject and supply the fuel into the intake port 17R. Note that the fuel injection valves 19L, 19R in the internal combustion engine 10 are provided in an inclined manner so as to be distanced from each other toward their tip end sides to be inserted into the intake ports 17L, 17R.
An intake manifold 20 that connects the intake ports 17L, 17R to a surge tank (not shown) in which the intake air from outside is stored temporarily is provided between the first cylinder head 16L and the second cylinder head 16R in the internal combustion engine 10. The intake manifold 20 is constituted by an upstream portion 22, a first downstream portion 33, and a second downstream portion 34. The upstream portion 22, the first downstream portion 33, and the second downstream portion 34 are provided separately.
As illustrated in
In an upstream end (an upper end in
In a downstream end (a lower end in
The first downstream portion 33 includes three first downstream passages 31 provided for the cylinders 15L on the first bank side. In an upstream end (an upper end in
Further, the second downstream portion 34 includes three second downstream passages 32 provided for the cylinders 15R on the second bank side. In an upstream end (an upper end in
Note that the first downstream portion 33 and the second downstream portion 34 of the intake manifold 20 are provided by die casting in which molten metal is filled into a die by applying a high pressure. In the intake manifold 20, the flange 27 in the upstream portion 22 is fixed to the flange 35 in the first downstream portion 33 with bolts, so that the first upstream passage 23 is connected to the first downstream passage 31. In the intake manifold 20, the flange 28 in the upstream portion 22 is fixed to the flange 36 in the second downstream portion 34 with bolts, so that the second upstream passage 24 is connected to the second downstream passage 32. Note that the first downstream portion 33 and the second downstream portion 34 are provided such that their downstream sides are distanced from each other as compared with their upstream sides in a state where they are connected to the upstream portion 22 as such.
In the internal combustion engine 10, the flange 25 in the upstream portion 22 of the intake manifold 20 is fixed to the surge tank with bolts. Hereby, the first upstream passage 23 and the second upstream passage 24 communicates with the surge tank is the upstream portion 22.
Then, the flange 37 in the first downstream portion 33 is fixed to the first cylinder head 16L with bolts, so that the first downstream passage 31 is connected to the intake port 17L of the first cylinder head 16L. That is, the first upstream passage 23 communicates with the intake port 17L of the first cylinder head 16L via the first downstream passage 31.
Further, the flange 38 in the second downstream portion 34 is fixed to the second cylinder head 16R with bolts, so that the second downstream passage 32 is connected to the intake port 17R of the second cylinder head 16R. That is, the second upstream passage 24 communicates with the intake port 17R of the second cylinder head 16R via the second downstream passage 32.
Note that a part between the flange 27 in the upstream portion 22 and the flange 35 in the first downstream portion 33 and a part between the flange 28 in the upstream, portion 22 and the flange 36 in the second downstream portion 34 are sealed by liquid gasket. Similarly, a part between the flange 37 in the first downstream portion 33 and the first cylinder head 16L and a part between the flange 38 in the second downstream portion 34 and the second cylinder head 16R are also sealed by liquid gasket.
In such an intake manifold 20, the intake air from outside is first introduced into the first upstream passage 23 and the second upstream passage 24 via the surge tank. Then, the intake air is supplied to the intake ports 17L, 17R of the first cylinder head 16L and the second cylinder head 16R from the first upstream passage 23 and the second upstream passage 24 via the first downstream passage 31 and the second downstream passage 32.
When the intake manifold 20 is assembled to the cylinder heads 16L, 16R in the internal combustion engine 10, the first downstream portion 33 is assembled to the first cylinder head 16L, and then, the fuel injection valve 19L is attached to the first cylinder head 16L so as to be able to inject the fuel into the intake port 17L. Further, after the second downstream portion 34 is assembled to the second cylinder head 16R, the fuel injection valve 19R is attached to the second cylinder head 16R so as to be able to inject the fuel into the intake port 17R. Then, the upstream portion 22 is assembled to the first downstream portion 33 and the second downstream portion 34.
Next will be described an operation and an effect of the intake manifold 20. When the fuel/air burns in the combustion chambers of the cylinders 15L, 15R in the internal combustion engine 10, the internal combustion engine 10 thermally expands outward along with that. Hereby, the cylinder heads 16L, 16R are displaced in directions to be distanced from each other. Note that a temperature of the intake manifold does not become as high as temperatures of the cylinder block 14 and the cylinder heads 16L, 16R because a distance of the intake manifold 20 from the cylinders 15L, 15R is farther as compared with distances of the cylinder block 14 and the cylinder heads 16L, 16R therefrom, and further the intake air circulates through the intake manifold 20. Accordingly, in the internal combustion engine 10, a degree of thermal expansion of the cylinder block 14 and the cylinder heads 16L, 16R tends to be larger than a degree of thermal expansion of the intake manifold 20. Accordingly, when such thermal expansion occurs, the first downstream portion 33 and the second, downstream portion 34 are pulled so as to be distanced from each other via their respective connection portions with the cylinder heads 16L, 16R.
In the intake manifold 20, when the internal combustion engine 10 thermally expands and the cylinder heads 16L, 16R are displaced in the directions to be distanced from each other, not only a positional displacement in a connection portion between the flange 37 in the first downstream portion 33 and the first cylinder head 16L, but also a positional displacement between the flange 35 of the first downstream portion 33 and the flange 27 of the upstream portion 22 might occur. By dispersing the parts where a positional displacement occurs as such, it is possible to reduce a degree of the positional displacement in the flange 37 of the first downstream portion 33. Accordingly, it is possible to restrain an excessive positional displacement that might decrease a sealing characteristic in the flange 37 of the first downstream portion 33.
The same can be said about the second downstream portion 34. That is, when the internal combustion engine 10 thermally expands and the cylinder heads 16L, 16R are displaced in the directions to be distanced from each other, not only a positional displacement in a connection, portion between the flange 38 in the second downstream portion 34 and the second cylinder head 16R but also a positional displacement between the flange 36 of the second downstream portion 34 and the flange 28 of the upstream portion 22 might occur. By dispersing the parts where a positional displacement occurs as such, it is possible to reduce a degree of the positional displacement in the flange 38 of the second downstream portion 34. Accordingly, it is possible to restrain an excessive positional displacement that might decrease a sealing characteristic in the flange 38 of the second downstream portion 34.
In the meantime, in the internal combustion engine 10, under the influence of restriction of a disposition space, and the like, the fuel injection valves 19L, 19R are provided so as to be inclined along the first downstream portion 33 and the second downstream portion 34, at a position close to the first downstream portion 33 and the second downstream portion 34, as illustrated in
In contrast, in the intake manifold 20, the first downstream portion 33 and the second downstream portion 34 that might interfere with the fuel injection valves 19L, 19R at the time of assembling are provided as different members from the upstream portion 22. On this account, as the assembling order, it is possible to employ an order of assembling the fuel injection valves 19L, 19R after the first downstream portion 33 and the second downstream portion 34 are assembled. Of course, it is possible to employ an order of assembling the upstream portion 22 after the first downstream portion 33 and the second downstream portion 34 are assembled, and then assembling the fuel injection valves 19L, 19R after the upstream portion 22 is assembled. That is, in the internal combustion engine 10 equipped with the intake manifold 20, the assembling order of the intake manifold 20 and the fuel injection valves 19L, 19R can be selected from more assembling orders than the conventional technique, and a degree of freedom of the assembling order improves.
Note that the upstream portion 22 in the intake manifold 20 is positioned on an extension line (an alternate long and short dash line in
Further, the intake manifold 20 is configured such that the upstream portion 22, the first downstream portion 33, and the second downstream portion 34 are provided in a divided manner. Here, the upstream portion 22 includes six passages constituted by two lines of the first upstream passages 23 and the second upstream passages 24. In the meantime, the first downstream portion 33 and the second downstream portion 34 each include three passages arranged in line, e.g., the first downstream passages 31 and the second downstream passages 32. As such, the first downstream portion 33 and the second downstream portion 34 have a relatively simple shape as compared with the upstream portion 22, so that the first downstream portion 33 and the second downstream portion 34 of the intake manifold 20 can be provided by die casting.
Like the above intake manifold 20, the first downstream portion 33 and the second downstream portion 34 provided by the die casting can be configured such that the first downstream passage 31 and the second downstream passage 32 have a side wall with a small thickness in comparison with those provided by a gravity casting process. When the side walls of the first downstream passage 31 and the second downstream passage 32 are reduced in thickness, it is possible to achieve a weight reduction of the intake manifold 20.
Note that the intake manifold 20 is configured such that the upstream portion 22, the first downstream portion 33, and the second downstream portion 34 are provided in a divided manner, so that a positional displacement might occur between the downstream end of the upstream portion 22 and the upstream end of the first downstream portion 33 or the second downstream portion 34. Due to the positional displacement, a stress in the intake manifold 20 is relaxed, so that it is possible to reduce a thickness of each part in comparison with the intake manifold in which the upstream portion 22, the first downstream portion 33, and the second downstream portion 34 are formed integrally, like the conventional intake manifold. Accordingly, from such a viewpoint, in comparison with the conventional intake manifold, the above configuration is advantageous in order to achieve the weight reduction of the intake manifold 20.
Further, the first downstream portion 33 and the second downstream portion 34 provided by the die casting can be configured such that the first downstream passage 31 and the second downstream passage 32 are provided with smooth inner surfaces, in comparison with those provided by the gravity casting process. On this account, it is possible to reduce a resistance that the intake air receives on the inner surfaces of the first downstream passage 31 and the second downstream passage 32 at the time when the intake air passes through the first downstream passage 31 and the second downstream passage 32.
Note that the above embodiment can be modified to the following other embodiments.
The upstream portion 22 may be further divided in the middle of an intake air flow direction of the first upstream passage 23 or the second upstream passage 24. Even with such a configuration, the number of parts where a positional displacement occurs in the intake manifold 20 further increases.
Number | Date | Country | Kind |
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2016-159269 | Aug 2016 | JP | national |