BRPI0801149B1 - INTERNAL COMBUSTION ENGINE - Google Patents

Abstract

internal combustion engine. the present invention relates to an internal combustion engine where it is intended to suppress an increase in the intake resistance and a decrease in the admission flow rate inside the intake port in an internal combustion engine that has two mutually opposing parts that project into the intake port. said internal combustion engine includes first and second protruding parts (24, 25) that protrude into an intake port (8) and in which the protruding parts (24, 25) extend along the direction flow rate inside the intake port (8) and are provided to be opposite each other as seen in a section orthogonal to the flow direction of the intake, the projecting top parts (24a, 25a) the projecting parts (24, 25) on the intake port (8) are arranged so that they are offset from each other in the direction of the intake flow.

Description

INTERNAL COMBUSTION ENGINE

[001] The present invention relates to an internal combustion engine that has an intake port that forms an intake passage leading to a combustion chamber.

BACKGROUND OF THE TECHNIQUE

[002] According to the related technique, the aforementioned internal combustion engine includes first and second projecting parts that project into the intake port from the wall surface of the intake port, and the projecting parts extend along the direction of admission flow within the admission port and are provided to be opposite each other as seen in a section cut orthogonal to the direction of admission flow (for example, see Patent Document 1). The projecting top parts of the projecting parts in the intake port are located in substantially the same position in the direction of the intake flow. As these projecting parts face each other to partially narrow the intake passage, a rectifying effect is given to the intake flow within the intake port and its flow rate distribution is changed to thereby obtain increased combustibility.

[003] Patent Document 1 JP-A No. 2007 - 9747

DESCRIPTION OF THE INVENTION PROBLEMS TO BE SOLVED BY THE INVENTION

[004] However, according to the configuration of the related technique mentioned above, since the projecting top parts of the projecting parts face each other in order to narrow the intake passage, there are cases where an increase in the intake resistance and a decrease in the admission flow rate is caused due to the excessive narrowing of the admission passage. Improvement in this regard is desired.

[005] Consequently, it is an objective of the present invention to suppress an increase in the intake resistance and a decrease in the intake flow rate within an intake port on an internal combustion engine that has mutually opposite projecting parts within the intake port. .

MEANS TO SOLVE THE PROBLEM

[006] As a means of solving the aforementioned problem, in one aspect of the invention, an internal combustion engine (for example, an engine 1 according to one embodiment) is provided including: a cylinder head (for example, a head cylinder 2 according to a modality) that forms a combustion space (for example, a combustion chamber 4a according to a modality) in cooperation with a cylinder (eg, a cylinder body 3 according to a modality) ; an inlet orifice (for example, an inlet orifice 8 according to one embodiment) provided in the cylinder head and which has an inlet opening (for example, an opening in the combustion chamber cable 8a according to one embodiment) that opens inside the combustion space; an intake valve (for example, an intake valve 6, according to an embodiment) for opening and closing the intake opening; a first and second projecting parts (for example, first and second projecting parts 24, 25 according to one embodiment) projecting into the inlet port from the wall surface of the inlet port, the projecting parts extending over a direction of inlet flow within the inlet orifice and being provided to be opposite each other as seen in a section cut orthogonal to the direction of the inlet flow, in which the projecting top parts (for example, top parts projectors 24a, 25a according to a modality) of the projecting parts into the inlet orifice are arranged to be displaced from each other in the direction of the inlet flow.

[007] In one aspect of the invention, an end part of a valve guide (e.g., a valve guide 6c according to one embodiment) through which a stem (e.g., a stem 6b according to one embodiment) ) of the inlet valve is inserted, it protrudes into the inlet port, one of the projecting parts (for example, a second projecting part 25 according to one embodiment) is provided on a wall surface of the inlet port in a side where the valve guide is provided, a projecting top part (for example, a projecting top part 25a according to one embodiment) of the projecting part is provided near the projecting end part of the valve guide and on one side a intake amount with respect to the projecting end part, an inclined part (for example, an inclined part of the upstream side 25b according to an embodiment) that extends at an inclination with respect to the direction of the intake flow from a su The wall surface of the intake hole for the projecting top part is provided on one side upstream of the intake with respect to the end part of the projecting part and the inclination of the inclined part becomes steeper near the top part.

[008] In one aspect of the invention, the inlet orifice is curved towards the inlet opening, the valve guide and the projecting part (for example, a second projecting part 25 according to one embodiment) are provided on one side curved external periphery of the intake orifice, and another projecting part (for example, a first projecting part 24 according to one embodiment) is provided on a curved external peripheral side of the admission orifice and a projecting top part (for example, a the projecting top part 24a according to one embodiment) of the other projecting part is provided on one side upstream of the intake with respect to the projecting top part (e.g., a projecting top part 25a according to one embodiment) of the projecting part.

EFFECT OF THE INVENTION

[009] According to one aspect of the invention, providing the projecting parts that extend in the direction of an intake flow into the intake orifice, a rectification effect is given to the intake flow into the intake orifice to provide a rate of increased intake flow, thus promoting the formation of a vortex flow within the combustion space due to the intake flow for increased combustibility. Furthermore, by displacing the projecting top parts of the projecting parts from one another in the direction of the intake flow, it is possible to suppress an increase in the intake resistance due to the excessive narrowing of the intake passage.

[0010] According to one aspect of the invention, when an intake flow into the intake port passes through the proximity of the projecting end part of a valve guide, the intake flow is guided by the sloping part of a projecting part and it passes over the projecting end part of the valve guide, thereby making it possible to suppress an increase in the intake resistance around the projecting end part of the valve guide. Furthermore, since the inclination of the inclined part becomes steeper near the projecting top part of a projecting part, an intake flow flowing along the inclined part can readily pass over the projecting end part of the valve guide.

[0011] According to one aspect of the invention while a part of the intake flow flowing along a curved outer peripheral side of the intake port passes through the projecting top part of the other projecting part and then flows along the inclined part in the downstream of the intake, its flow direction is changed towards the curved inner peripheral side of the intake orifice. Likewise, while a portion of an intake flow flowing along the curved outer peripheral side of the intake orifice flows along the angled part on the upstream side of the intake with respect to the projecting top part of the projecting part, its direction of flow is shifted towards the curved inner peripheral side of the intake port. It is therefore possible to provide increased flow rate on the curved inner peripheral side where an intake flow rate tends to easily decrease, thus ensuring a high intake flow rate making the use of the entire cross section of the intake port effective.

BEST WAY TO PERFORM THE INVENTION

[0012] In the following, an embodiment of the present invention will be described with reference to the drawings.

[0013] Figure 1 is a side view of a cylinder head 2 of a single cylinder OHC four-cylinder engine 1 used as the main engine of a vehicle such as a motorcycle, for example. A valve chamber 4 is formed inside the cylinder head 2, and a valve gear 5 for driving the intake and exhaust valves 6, 7 is accommodated inside the valve chamber 4. The cylinder head 2 is mounted at the distal end of a cylinder body 3. A combustion chamber 4a of the engine 1 is formed by the cylinder head 2 and the cylinder body 3. It should be noted that the symbol C1 in the drawing indicates the central geometric axis (geometric axis of the cylinder) of the cylinder bore inside the cylinder body 3.

[0014] Inlet and exhaust ports 8, 9 are formed inside the cylinder head 2. The openings on the side of the combustion chamber 8a, 9a of the intake and exhaust ports 8, 9 are opened or closed respectively by the intake valves and exhaust 6, 7. Furthermore, the intake and exhaust ports 8, 9 respectively, have openings on the outside of cylinder 8b, 9b that open on the right outer wall and the left outer wall of cylinder head 2 in figure 1. Each one of the openings on the outside of cylinder 8b, 9b, are provided so as to extend along a plane substantially parallel to the geometric axis of cylinder C1.

[0015] Inlet and exhaust holes 8, 9 extend from the openings on the outside of cylinder 8b, 9b towards the central side of the cylinder (side of cylinder geometric axis C1) along a direction generally orthogonal to the axis cylinder geometric C1 (direction orthogonal to the cylinder), and then its parts on the central side of the cylinder are curved towards the side of the combustion chamber 4a to reach the openings on the side of the combustion chamber 8a, 9a. Each of the openings on the side of the combustion chamber 8a, 9a are provided along a plane that is inclined so that the central side of the cylinder is located on the side of the valve chamber 4 (side of the distal end of the cylinder head 2 ).

[0016] Valves 6, 7 have rod-like rods 6b, 7b extending to the side of the valve chamber 4 from the umbrella-shaped valve bodies 6a, 7a that conform to the openings on the side of the chamber combustion 8a, 9a of the orifices 8, 9. The rods 6b, 7b are held by the cylinder head 2 by means of the tubular valve guides 6c, 7c in a manner that allows the reciprocating movement.

[0017] Retainers 6d, 7d are mounted to the distal ends of the rods 6b, 7b of the valves 6, 7. Due to the spring forces of the springs 6e, 7e provided under compression between the retainers 6d, 7d and the cylinder head 2, valves 6, 7 are propelled next to valve chamber 4, thus bringing their valve bodies 6a, 7a in close contact with the openings on the side of the combustion chamber 8a, 9a to close the openings on the side of the combustion chamber 8a , 9a. On the other hand, while valves 6, 7 are displaced towards the combustion chamber side 4a against the pushing forces of the springs 6e, 7e, the valve bodies 6a, 7a of valves 6, 7 separate from the openings on the side of the combustion chamber 8a, 9a to open the openings on the side of the combustion chamber 8a, 9a.

[0018] Stems 6b, 7b of valves 6, 7 are provided at an inclination with respect to the cylinder axis C1 so as to form a V-shape that opens towards the side of valve chamber 4 in figure 1. An axis camshaft 11 arranged to be orthogonal to the plane of figure 1 is provided between the extended end sides of the rods 6b, 7b. During engine 1 operation, the camshaft 11 is driven to rotate together with a crankshaft by means of a chain type transmission mechanism, for example (both not shown). It should be noted that the symbol C2 in the drawing indicates the center of rotation of the camshaft 11.

[0019] Valves 6, 7 are actuated to open and close while they are pressed by the intake and exhaust cams 11a, 11b of the camshaft 11 by means of the holding arms 12, 13 on the intake side and exhaust side. The axles of the holding arms 14, 15 on the intake side and exhaust side parallel to the camshaft 11 are arranged respectively on the side of the distal end of the cylinder head 2 with respect to the camshaft 11 and on the side of the intake valve 6 and exhaust valve side 7. The longitudinal intermediate parts of the gripping arms 12, 13 are supported oscillatingly on the axes of the gripping arms 14, 15. In each of the gripping arms 12, 13 a roller cam 16, which is provided to roll on the outer peripheral surface (cam surface) of each of the cams 11a, 11b, is supported on an end part on the camshaft side 11, and a pusher screw 17 that abuts on the distal end of the stem is supported on the end part on the side of the stem.

[0020] While the camshaft 11 is driven to rotate during engine 1 operation, the clamping arms 12, 13 oscillate according to cam cam patterns 11a, 11b so that valves 6, 7 have reciprocating movement along its rods in order to open and close the openings on the side of the combustion chamber 8a, 9a of the holes 8, 9.

[0021] At the opening of the intake valve 6, an air-fuel mixture of external air and fuel flows into the intake port 8, from the opening on the outside of cylinder 8b as its end on the side upstream of the intake. This air-fuel mixture flows into the combustion chamber 4a from the opening on the side of the combustion chamber 8a, like the side downstream of the intake port 8. The air-fuel mixture is compressed after the intake valve 6, it is closed, and ignited by a spark plug (not shown) for combustion. The exhaust gas after combustion is discharged to the outside of the combustion chamber 4a through the exhaust port 9 when the exhaust valve 7 is opened.

[0022] The inlet hole 8 of engine 1 will be described in detail below, with reference to figures 2, 3.

[0023] The inlet orifice 8 extends from the opening on the outside of the cylinder 8b to the opening on the side of the combustion chamber 8a, although having a generally constant cross-sectional area. That is, the cross-sectional area of the intake passage formed by the intake port 8 is generally constant.

[0024] The cross-sectional shape of the intake port 8 orthogonal to the longitudinal direction at each proximity to the opening on the outside of the cylinder 8b and the proximity to the opening on the combustion chamber side 8a (at the longitudinal end parts) is a circle perfect, having no convex part inside. On the other hand, the aforementioned cross-sectional shape of the inlet orifice 8 between the opening on the outside of the cylinder 8b and the opening on the side of the combustion chamber 8a (in the middle longitudinally) is a different shape having inward convex parts .

[0025] As described above, the intake port 8 extends from the opening on the outside of the cylinder 8b to the central side of the cylinder along a direction generally orthogonal to the cylinder, and then its part on the downstream side of the intake is curved towards the combustion chamber side 8a. Here after the curved part of the inlet hole 8 on the inlet downstream side mentioned above it will be referred to as a curved part 22. The symbol C3 in the drawing denotes a center line through the door that extends along the longitudinal direction (extended direction / inlet flow direction) of the inlet port 8 while passing through the central position of the inlet port cross-section shape 8.

[0026] More specifically, from the opening on the external side of the cylinder 8b to the central side of the cylinder, the intake port 8 extends at a slight inclination so as to be located closer to the side of the valve chamber 4 with increasing proximity to the side of the center of the cylinder with respect to the direction orthogonal to the cylinder, and is slightly curved to be convex to the side of valve chamber 4. Then, inlet port 8 then extends at a slight slope on its side downstream of intake so as to be located closer to the side of the combustion chamber 4a with increasing proximity to the side of the cylinder center with respect to the direction orthogonal to the cylinder (the part of the intake orifice 8 up to this point is referred to as an upstream part 21 ), the inlet orifice part 8 located on the even further downstream side of the inlet (the curved part 22) is curved towards the side of the combustion chamber 4a as described above, and reaches the opening of the l of the combustion chamber 8a while having its radius of curvature increased (with its curve made more closed) and its inclination towards the side of the combustion chamber 4a made steeper.

[0027] That is, the inlet orifice 8 is generally curved as a whole with its side downstream of the intake directed towards the side of the combustion chamber 4a, and varies in radii of curvature so that its curve becomes more closed in the downstream of the admission. Here after the side of the valve chamber 4 in the inlet port 8 it is referred to as the curved outer peripheral side, and the side opposite this side is referred to as the curved inner peripheral side.

[0028] In this case, on the curved internal peripheral side of the upstream part 21 of the inlet orifice 8, a first projecting part 24 is provided from its wall surface to the internal side of the cross section of the door.

[0029] The first projecting part 24 is provided so as to extend along the direction of intake flow, and form a projecting surface in a circular arc shape that is convex towards the inner side of the cross section of the door as seen in a cross section shown in figures 3 (b), 3 (c) (as seen in a cross section orthogonal to the direction of the intake flow). It should be noted that a part of removed material 27 is formed on the curved outer peripheral side of the intake port 8 in order to ensure the cross-sectional area (intake passage area) of the intake port 8 reduced by the projection of the first projecting part 24.

[0030] The first projecting part 24 projects in the form of a smooth circular arc elongated in the direction of the intake flow in figure 2. The end parts of the first projecting part 24 on the upstream side of the intake and the downstream side are formed smoothly continuous to the wall surface of the intake port 8. The radius of curvature of the curved inner peripheral side of the upstream part 21 of the inlet port 8 thus becomes partially large, thereby reducing the variation in curvature between the upstream part 21 and the curved part 22 on the curved inner peripheral side.

[0031] Therefore, after a portion of an intake flow flowing along the curved inner peripheral side of the intake port 8 is shifted in its flow direction to the curved inner peripheral side along the first projecting part 24, the flow inlet can readily flow along the curved inner peripheral side of the curved part 22 as well. This prevents the separation of the intake flow from the wall surface of the inner peripheral side of the curved part 22 on the downstream side of the intake (particularly the curved part 22) of the intake port 8, thereby suppressing resistance to the intake. Furthermore, an intake flow rate increases on the curved inner peripheral side within the intake orifice 8 where an intake flow rate tends to decrease easily, thereby facilitating the control of an intake flow (particularly a drop flow ( vortex flow in the vertical direction of the cylinder)) flowing into the combustion chamber 4a. In this regard, a drop flow generated within the combustion chamber 4a can be controlled not only by suppressing the separation of the intake flow, but also by varying the projecting height of the first projecting part 24 and its position in the direction of the intake flow. as appropriate to purposely cause separation of the admission flow mentioned above.

[0032] From now on, the top projecting part of the first projecting part 24 towards the inner side of the door cross section is denoted by the symbol 24a, and the sloping parts on the upstream side of the intake and downstream side (inclined part upstream side and sloping part of the downstream side) with respect to the projecting top part 24a respectively denoted by symbols 24b, 24c.

[0033] On the other hand, a second projecting part 25 is provided on the curved outer peripheral side of the intake hole 8, projecting from the wall surface of it towards the internal side of the cross section of the door.

[0034] The second projecting part 25 is provided so as to extend along the direction of the intake flow, and form a projecting surface of a circular arc shape that is convex to the internal side of the cross section of the door as seen in a cross section shown in figures 3 (c), 3 (d) (as seen in a cross section orthogonal to the direction of the intake flow). It should be noted that the aforementioned removed material part 27 is continuously formed on the sides of the second projecting part 25 on the curved outer peripheral side of the intake port 8.

[0035] The second projecting part 25 projects in the form of an elongated badge in the direction of the intake flow in figure 2. Additionally, the part of the second projecting part 25 on the upstream side of the admission with respect to its projecting top part 25a towards the inner side of the cross section of the door it is formed elongated in the direction of the intake flow, and its end part located further on the side upstream of the intake is formed smoothly continuous to the wall surface of the intake hole 8. A the projecting top part 25a of the second projecting part 25 is generally located on the boundary between the upstream part 21 and the curved part 22. Here after the inclined parts on the upstream side of the mission and the downstream side (inclined part on the upstream and inclined part of the downstream side) in relation to the projecting top part 25a of the second projecting part 25 are denoted respectively by symbols 25b, 25c.

[0036] In this respect, on the curved outer peripheral side of the curved part 22, and the combustion chamber side end part 4a of the valve guide 6c to the intake valve 6 protrudes into the inner side of the door cross section . The valve guide 6c is arranged orthogonal to the opening on the side of the combustion chamber 8a, and its end part on the side of the combustion chamber 4a (projecting end part) projects so as to be directed towards the center of the opening on the side of the combustion chamber 8a. The center line of valve guide 6c coincides with a tangent to the center line of port C3 at the opening position on the combustion chamber side 8a (a straight line passing through the center of the opening on the combustion chamber side 8a and sloping in order to be located closer to the center side of the cylinder with increasing proximity to the side of the cylinder body 3).

[0037] The projecting end part of the valve guide 6c extends through the second projecting part 25, and its distal end is exposed on the sloping part of the downstream side 25c in the second projecting part 25 which is formed relatively short in relation to the direction of the intake flow The top projecting part 25a of the second projecting part 25 is located on the side immediately upstream of the admission of the distal end of the valve guide 6c and the inclined part of the downstream side 25b which is formed relatively long in relation to the direction of the intake flow is provided on the upstream side of the intake of the projecting top part 25a. The sloping part of the downstream side 25b is formed as a ramp that rises smoothly from the wall surface on the upstream side of the upstream part 21 and reaches the projecting top part 25a.

[0038] Consequently, a portion of an intake flow flowing along the curved outer peripheral side of the intake port 8 changes its flow direction to the curved inner peripheral side along the second projecting part 25, and flows to the side a downstream of the intake so as to be able to pass over the projecting end part of the valve guide 6c, thus suppressing resistance (reaction) to the intake flow passing through the proximity of the projecting end part of the valve guide 6c.

[0039] Still more specifically, the sloping part of the downstream side 25b is slightly curved to form an outer surface of a circular arc shape which is convex towards the side of the valve chamber 4 in figure 2, and increases in curvature in order to make its slope steeper (make its curve more closed) close to the projecting top part 25a.

[0040] Consequently, while a part of an intake flow within the intake port 8 passes through the projecting top part 25a of the second projecting part 25, a direction towards the inner side of the door cross section and therefore towards the curved internal peripheral side is driven to the intake flow, thereby increasing the admission flow rate on the curved internal peripheral side while suppressing the separation of the intake flow from the wall surface on the curved internal peripheral side. It should be noted that the projection height of the projecting top part 25a of the second projecting part 25 towards the curved internal peripheral side of the door cross section is greater than that of the projecting end part of the valve guide 6c.

[0041] The projecting parts 24, 25 are provided respectively on the curved inner peripheral side and the curved outer peripheral side of the intake port 8 so that they are opposite each other through the center line of the door C3 as seen in the cross section shown in figure 3 (c).

[0042] In this regard, as shown in figure 2, the projecting top parts 24a, 25a are arranged in such a way that their positions in the direction of the intake flow are offset from one another. Specifically, the projecting top part 24a of the first projecting part 24 is arranged to be moved to the side upstream of the intake in the direction of the intake flow with respect to the projecting top part 25a of the second projecting part 25 (in in other words, the projecting top part 25a of the second projecting part 25 is moved to the downstream side of the intake with respect to the projecting top part 24a with respect to the first projecting part 24). This prevents excessive narrowing of the intake passage due to the provision of the projecting parts 24, 25 inside the intake orifice 8.

[0043] As shown in figure 4, in the part that forms the roof of the combustion chamber 4a in the cylinder head 2, a spark plug insertion opening 28 towards which the electrode part of the above spark plug is facing is provided in a location that avoids interference with the openings on the side of the combustion chamber 8a, 9a of the holes 8, 9. In the engine 1 according to the present application, the positions and shapes of the projecting parts 24, 25 are fixed so that the aforementioned air-fuel mixture (intake flow) gathers around the plug insertion opening 28, thus obtaining optimization of the drop flow and swirl-flow (vortex flow in the transverse direction of the cylinder) admission flow.

[0044] Suppressing an inlet resistor and increasing an inlet flow rate within the inlet orifice 8 as described above, as shown in figure 5, in engine 1 according to the present application which has projecting parts 24, 25 provided in the intake port 8, the effective power of the engine at full throttle (effective power WOT (Wide Open Strangulator)) is increased across the entire speed range of the engine compared to a related engine that does not have the projecting parts 24 , 25. Furthermore, by actively controlling the intake flow within the combustion chamber 4a as described above, engine 1 according to the present invention also makes it possible to increase the combustibility of an air-fuel mixture to obtain improved fuel economy performance. fuel.

[0045] It should be noted that, as shown in figure 1, a projecting part 29 corresponding to the second projecting part 25 is provided around the projecting end part of the valve guide 6c on the curved outer peripheral side of the exhaust port 9, in this way suppressing a vortex flow on the downstream side of the intake of the projecting end part of the valve guide 6c to suppress escape resistance.

[0046] As described above, the engine 1 according to the version mentioned above includes: the cylinder head 2 forming the combustion chamber 4a in cooperation with the cylinder body 3; the inlet orifice 8 provided in the cylinder head 2 and having the opening on the side of the combustion chamber 8a that opens in the combustion chamber 4a; the intake valve 6 for opening and closing the opening on the combustion chamber side 8a and the first and second projecting parts 24, 25 projecting into the inlet port 8 from the wall surface of the inlet port 8. The projecting parts 24, 25 extend along an inlet flow direction within the inlet orifice 8 and are provided to be opposite each other as seen in a cross-section orthogonal to the inlet flow direction. The projecting top parts 24a, 25a of the projecting parts 24, 25 into the inlet orifice 8 are arranged to be displaced from one another in the direction of the inlet flow.

[0047] In accordance with this configuration, providing the projecting parts 24, 25 that extend along the direction of an intake flow within the intake orifice 8, a rectification effect is given to the intake flow within the intake orifice 8 to provide increased intake flow rate, thereby promoting the formation of a vortex flow within the combustion chamber 4a due to the intake flow for increased combustibility. Furthermore, by displacing the projecting top parts 24a, 25a from the projecting parts 24, 25 from one another in the direction of the intake flow, it is possible to suppress an increase in the intake resistance due to the excessive narrowing of the intake passage.

[0048] Furthermore, in the engine 1 mentioned above, an end part of the valve guide 6c, through which the stem 6b of the intake valve 6 is inserted, protrudes into the intake hole 8, the second projecting part 25 is provided on the wall surface of the inlet hole 8 on the side where the valve guide 6c is provided, the projecting top part 25a of the second projecting part 25 is provided near the projecting end part of the valve guide 6c and on the side upstream of the intake with respect to the projecting end part, the sloping part of the downstream side 25b which extends at an inclination with respect to the direction of the intake flow from the wall surface of the intake hole 8 to the projecting top part 25a is provided on the upstream side of the intake with respect to the projecting top part 25a of the second projecting part 25, and the inclination of the inclined part of the downstream side 25b becomes steeper near the projecting top part 25a .

[0049] According to this configuration, when an intake flow within the inlet orifice 8 passes through the proximity of the end part of the valve guide 6c, the intake flow is guided by the inclined part of the downstream side 25b of the second projecting part 25 and passes over the projecting end part of the valve guide 6c, thereby making it possible to suppress an increase in intake resistance around the projecting end part of the valve guide 6c. Furthermore, since the inclination of the sloping part of the downstream side 25b becomes steeper near the projecting top part 25a of the second projecting part 25, an intake flow flowing along the sloping part of the downstream side 25b can readily pass over the projecting end part of the valve guide 6c.

[0050] Furthermore, in the engine 1 mentioned above, the intake port 8 is curved towards the opening on the side of the combustion chamber 8a, the valve guide 6c and the second projecting part 25 are provided on the curved outer peripheral side of the intake port 8, the first projecting part 24 is provided on the curved inner peripheral side of the intake orifice 8, and the projecting top part 24a of the first projecting part 24 is provided on the upstream side of the admission in relation to the projecting top part 25a of the second projecting part 25.

[0051] According to this configuration, while a part of the intake flow flowing along the curved outer peripheral side of the intake port 8 passes through the projecting top part 24a of the first projecting part 24 and then flows along the inclined part downstream side 24c, its flow direction is changed towards the curved inner peripheral side of the intake port 8. Likewise, while a portion of the inlet flow flowing along the curved outer peripheral side of the intake orifice 8 flows along the sloping part of the downstream side 25b of the second projecting part, its flow direction is changed towards the curved inner peripheral side of the inlet hole 8. It is thus possible to provide increased admission flow rate on the inner peripheral side curved where an intake flow rate easily tends to decrease, thus ensuring a high intake flow rate making the use of the entire cross section of the orifice effective admission number 8.

[0052] It should be understood that the present invention is not limited to the above mentioned modalities. For example, the present invention can be applied to a four-valve engine or DOC engine, or even more a parallel or V multi-cylinder engine.

[0053] It is needless to mention that the configuration according to the aforementioned modality is an illustrative example of the present invention, and several modifications are possible without departing from the scope of the present invention.

BRIEF DESCRIPTION OF THE DRAWINGS

[0054] Figure 1 is a longitudinal sectional view of a cylinder head of an engine according to an embodiment of the present invention.

[0055] Figure 2 is an enlarged view of a part around an intake orifice in Figure 1.

[0056] Figure 3 (a) is a sectional view taken along line AA in figure 2, figure 3 (b) is a sectional view taken along line BB in figure 2, figure 3 (c) is a sectional view taken along line CC in figure 2, figure 3 (d) is a sectional view taken along line DD in figure 2, figure 3 (e) is a sectional view taken along line EE of figure 2,

[0057] Figure 4 is a plan view explaining the proximity of the engine as seen in the direction of the cylinder's geometric axis.

[0058] Figure 5 is a graph showing the variation in the effective power of the engine at full acceleration with respect to the engine speed in the engine and engine of the related technique.
REFERENCE LISTING
1 .. .. Engine (internal combustion engine)
2 Cylinder head
3 .. .. Cylinder head body (cylinder)
4th ... Combustion chamber (combustion space)
6 Inlet valve
6b ... Rod
6c .. Valve guide
8 Inlet port
8a ... Opening on the combustion chamber side (inlet opening)
24 .. .. First projecting part (the other projecting part)
24a ... Projecting top part
25 .. .. Second projecting part (one projecting part)
25a ... Projecting top part
25b ... Sloping part of the upstream side

Claims (2)

Internal combustion engine (1) comprising: a cylinder head (2) that forms a combustion space (4a) in cooperation with a cylinder (3); an inlet orifice (8) provided in the cylinder head (2) and which has an inlet opening (8a) that opens into the combustion space (4a); an intake valve (6) for opening and closing the intake opening (8a); and a first and second projecting parts (24, 25) projecting into the inlet port (8) from the wall surface of the inlet port (8), the projecting parts (24, 25) extending over a direction of inlet flow within the inlet orifice (8) and being provided so as to be opposite each other as seen in a section in section orthogonal to the direction of the intake flow, characterized by the fact that
the projecting top parts (24a, 25a) of the projecting parts (24, 25) in the intake port (8) are arranged so that they are offset from each other in the direction of the intake flow, and
an end part of a valve guide (6c) through which a stem (6b) of the inlet valve (6) is inserted, protrudes into the inlet orifice (8), one (25) of the projecting parts ( 24, 25) is provided on a wall surface of the intake port (8) on one side where the valve guide (6c) is provided (6c), the projecting top part (25a) of the projecting part (25) is provided near the projecting end part of the valve guide (6c) and on one side upstream of the intake with respect to the projecting end part, an inclined portion (25b) extending at an inclination with respect to the flow direction of inlet from the wall surface of the inlet hole (8) to the projecting top part (25a) which is provided on an inlet upstream side with respect to the projecting end part (25a) of the projecting part (25) , and the inclination of the inclined part (25b) becomes steeper near the projecting top part (25a). Internal combustion engine (1) according to claim 1, characterized by the fact that the inlet orifice (8) is curved towards the inlet opening (8a), the valve guide (6c) and a part projecting part (25) are provided on a curved outer peripheral side of the intake port (8), the other projecting part (24) is provided on a curved inner peripheral side of the intake port (8), and a projecting top part ( 24a) of the other projecting part (24) is provided on one side upstream of the intake with respect to the projecting top part (25a) of the projecting part (25).

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