Patent Application
20080168967
The present invention relates to a four-cycle internal combustion engine having an exhaust gas re-circulation device (EGR), and a vehicle including such a four-cycle internal combustion engine.
Conventionally, four-cycle internal combustion engines having an exhaust gas re-circulation device (EGR) for returning a portion of the exhaust gas (burnt gasses) to a combustion chamber are widely used. The EGR slows down combustion of a fuel/air mixture in a combustion chamber, lowers the highest combustion temperature, and reduces nitrogen oxides (NOX). For example, an EGR including a gas storage chamber is known, in which an auxiliary exhaust valve is provided at an auxiliary exhaust port coupled to a combustion chamber and a portion of the burnt gasses (EGR gas) discharged via the auxiliary exhaust port is stored in the gas storage chamber (see JP-A-Hei 05-086992, page 6, FIGS. 17 and 18, for example). In such an EGR, the EGR gas stored in the storage chamber is returned to the combustion chamber at a predetermined timing.
A four-cycle internal combustion engine having the EGR disclosed in JP-A-Hei 05-086992 requires a main exhaust port and a main exhaust valve, and an auxiliary exhaust port and an auxiliary exhaust valve in addition. Therefore, there is a problem that the structure of a cylinder head is complicated and production cost becomes expensive especially with a multi-cylinder four-cycle internal combustion engine having a plurality of cylinder sections.
In order to overcome the problems described above, preferred embodiments of the present invention provide a four-cycle internal combustion engine having a plurality of cylinder sections in which a structure of a cylinder head is not complicated, fuel consumption can be improved, and nitrogen oxides (NOX) can be reduced, and also provide a vehicle including such a novel four-cycle internal combustion engine.
According to a preferred embodiment of the present invention, a four-cycle internal combustion engine includes a plurality of cylinder sections each including a cylinder and an exhaust passage in communication with the inside of the cylinder, in which the cylinder section is in communication with the exhaust passage and has a cylinder-sided passage section in communication with the exhaust passage, through which burnt gasses pass, and the engine further including an inter-cylinder passage in communication with a plurality of the cylinder-sided passage sections.
With such a four-cycle internal combustion engine, an internal EGR amount can be made larger than those in conventional cases, and thus a pumping loss decreases. Also, the four-cycle internal combustion engine has the cylinder-sided passage in communication with the exhaust passage through which burnt gasses pass, and the inter-cylinder passage in communication with a plurality of the cylinder-sided passages. Therefore, differently from a conventional EGR, the engine needs to have no special intake or exhaust passage in communication with a gas storage chamber, or an intake and exhaust valve.
With such unique features, the structure around a cylinder head is not complicated even though the engine has a plurality of cylinder sections, fuel consumption can be improved, and nitrogen oxides (NOX) can be reduced.
According to another preferred embodiment of the present invention, a four-cycle internal combustion engine is constructed in accordance with the preferred embodiment of the present invention described above, and such that a direction in which the burnt gasses are introduced into the cylinder-sided passage section is a direction along a periphery of the cylinder, as seen from an axial view of the cylinder.
It is preferable that the cylinder section includes an exhaust valve for opening or closing the exhaust passage; and a time period during which the exhaust valve of one cylinder section is opened overlaps at least partially another time period during which the exhaust valve of another cylinder section is opened.
The four-cycle internal combustion engine preferably includes a crankshaft and a valve actuating mechanism for opening or closing the exhaust valve at a predetermined period with rotation of the crankshaft.
It is also preferable that the cylinder section includes an intake passage in communication with the inside of the cylinder; a direction in which a fluid is taken into the inside of the cylinder via the intake passage is the direction along the periphery of the cylinder, as seen from the axial view of the cylinder; and a direction in which the burnt gasses are introduced corresponds to a direction in which the fluid is swirled about an center axis of the cylinder.
The cylinder section preferably includes an intake passage in communication with the inside of the cylinder, and an intake valve for opening or closing the intake passage, and a period during which the exhaust valve opens overlaps a period during which the intake valve opens.
The inter-cylinder passage preferably extends along an arrangement of the plurality of the cylinder sections, and the cylinder-sided passage section branches from the inter-cylinder passage and extends toward the exhaust passage.
The cylinder-sided passage section preferably is directed to an exhaust passage opening that is open to the inside of the cylinder.
It is preferable that the exhaust passage is formed in a cylinder head; and the inter-cylinder passage and the cylinder-sided passage section are formed, on an exhaust passage side, in the cylinder head.
The cylinder head preferably has a surface that is arranged to mate with a cylinder block which forms the cylinder; and the inter-cylinder passage has an opening portion that is open toward the mating surface.
The opening portion preferably is blocked in a manner such that the cylinder head and the cylinder block are assembled together.
According to another preferred embodiment of the present invention, a vehicle includes a four-cycle internal combustion engine according to any one of above-described preferred embodiments of the present invention.
According to various preferred embodiments of the present invention, a four-cycle internal combustion engine having plural number of cylinders further improves fuel consumption and reduction of nitrogen oxides (NOX) without the structure of the cylinder head being complicated, and also a vehicle includes such a novel four-cycle internal combustion engine is provided.
Other features, elements, processes, steps, characteristics and advantages of the present invention will become more apparent from the following detailed description of preferred embodiments of the present invention with reference to the attached drawings.
Next, preferred embodiments of the vehicle according to the present invention will be described with reference to the accompanying drawings. The same or similar reference numerals and symbols are given to the same or similar parts in expressions of the following drawings. However, attention should be paid on that the drawings are schematic figures and the proportions of the objects are different from the reality.
Therefore, specific sizes and so forth should be determined referring the following descriptions. Also, it is a matter of course that the relationships between sizes or the proportions of the objects are different mutually between the drawings.
The engine 100 preferably is a four-cycle engine. A sprocket 170 rotating together with a camshaft (not shown) is disposed above a cylinder head 110sh (not shown in
A cam chain 180 is engaged with a crankshaft 160, which is actually a sprocket (not shown) rotating together with the crankshaft 160, and the sprocket 170.
An intake pipe 30 in communication with intake ports 110in to 140 in (not shown in
As shown in
The first cylinder section 110 has a cylinder 110S. Specifically, the cylinder 110S is formed with a cylinder block 110sb (see
The first cylinder section 110 has the intake port 110in and the exhaust port 110ex. Specifically, the intake port 110in and the exhaust port 110ex are formed with the cylinder head 110sh (see
The intake port 110in is in communication with the inside of the cylinder 110S. In this preferred embodiment, the intake port 110in defines an intake passage.
Similarly to the intake port 110in, the exhaust port 110ex is in communication with the inside of the cylinder 110S. In this preferred embodiment, the exhaust port 110ex defines an exhaust passage.
As shown in
An exhaust valve 112 is disposed at the exhaust port 110ex. The exhaust valve 112 opens or closes the exhaust port 110ex at a predetermined period.
A coil spring (not shown) for urging the intake valve 111 in a direction that closes the intake port 110in is mounted on the intake valve 111. Similarly, a coil spring (not shown) for urging the exhaust valve 112 in a direction that closes the exhaust port 110ex is mounted on the exhaust valve 112.
That is, the intake valve 111 opens or closes the intake port 110in at a predetermined period by rotation of the camshaft together with the sprocket 170. Similarly, the exhaust valve 112 opens or closes the exhaust port 110ex at a predetermined period by rotation of the camshaft together with the sprocket 170. In this preferred embodiment, the sprocket 170 and the cam chain 180 (see
The second cylinder section 120, the third cylinder section 130, and the fourth cylinder section 140 each preferably have a construction that is substantially similar to the first cylinder section 110.
The second cylinder section 120 preferably has a cylinder 120S, the intake port 120 in, and the exhaust port 120ex. An intake valve 121 is disposed at the intake port 120in. An exhaust valve 122 is disposed at the exhaust port 120ex.
The third cylinder section 130 preferably has a cylinder 130S, the intake port 130 in, and the exhaust port 130ex. An intake valve 131 is disposed at the intake port 130in. An exhaust valve 132 is disposed at the exhaust port 130ex.
Similarly, the fourth cylinder section 140 preferably has a cylinder 140S, the intake port 140 in, and the exhaust port 140ex. An intake valve 141 is disposed at the intake port 140in. An exhaust valve 142 is disposed at the exhaust port 140ex.
Each of the first cylinder section 110, the second cylinder section 120, the third cylinder section 130, and the fourth cylinder section 140 has a cylinder-sided passage in communication with the exhaust port, through which burnt gasses (EGR gas) pass. For example, the first cylinder section 110 has a cylinder-sided passage 151. Similarly, the second cylinder section 120, the third cylinder section 130, and the fourth cylinder section 140 have cylinder-sided passages 152, 153, and 154, respectively.
The cylinder-sided passages 151 to 154 are in communication with an inter-cylinder passage 150. That is, the inter-cylinder passage 150 is in communication with a plurality of the cylinder-sided passages. The inter-cylinder passage 150 is arranged along the axial direction of the crankshaft 160 so as to extend in a direction in which a plurality of the cylinders is arranged.
As shown in
As shown in
The inter-cylinder passage 150 and the cylinder-sided passage 151 are formed in the cylinder head 110sh on the side that the exhaust port 110ex is formed.
Burnt gasses supplied from another cylinder section (specifically, the second cylinder section 120) via the inter-cylinder passage 150 and the cylinder-sided passage 151 are introduced into the inside of the cylinder 110S through the opening 151a. The direction of the cylinder-sided passage 151, specifically, a direction of the burnt gasses introduced into the cylinder 110S through the opening 151a, is a direction along a periphery 110p of the cylinder 110S (see
The cylinder head 110sh and the cylinder block 110sb are coupled together through a gasket 190. That is, the cylinder head 110sh has a surface mating with the cylinder block 110sb, which is a plain surface contacting the gasket 190 in this preferred embodiment.
Further, the inter-cylinder passage 150 has an opening 150a open to the surface mating with the cylinder block 110sb. The inter-cylinder passage 150 defines a closed space in such a manner that the cylinder head 110sh and the cylinder block 110sb are combined together to block the opening 150a.
The volume (a cross sectional area in the direction of a smaller diameter) of the inter-cylinder passage 150 is larger than that of the cylinder-sided passage 151 (152, 153 or 154). In addition, the cylinder-sided passages 152, 153, 154 each have a shape similar to the cylinder-sided passage 151.
Next, an operation of the engine 100 of the four-cycle internal combustion engine in this preferred embodiment will be described. Specifically, descriptions will be made about a flow of burnt gasses occurring with operations of the intake valves and the exhaust valves of the engine 100.
In
A period during which the exhaust valve of any one of the cylinder sections opens, for example, the exhaust valve 112 opens in the first cylinder section 110 overlaps at least partially a period during which the exhaust valve of the cylinder section other than the first cylinder section 110, specifically, the exhaust valve 132 of the third cylinder section 130 opens.
That is, the engine 100 includes the four cylinder sections (the first cylinder section 110, the second cylinder section 120, the third cylinder section 130, and the fourth cylinder section 140). A period during which an exhaust valve (the exhaust valve 112) in any one of the cylinder sections (for example, the first cylinder section 110) opens overlaps at least partially a period during which an exhaust valve (the exhaust valve 132) opens.
Also, in each of the cylinder sections, a period during which the exhaust valve opens overlaps a period during which the intake valve opens.
With the engine 100, an internal EGR amount can be made larger than that in a conventional exhaust gas re-circulation device (EGR), and thus a pumping loss can be reduced. Therefore, a throttle valve (not shown) of the engine 100 is set more open, thereby improving the fuel consumption.
The engine 100 has the cylinder-sided passages 151 to 154 in communication with the exhaust ports through which burnt gasses pass, and the inter-cylinder passage 150 in communication with the cylinder-sided passages 151 to 154. Therefore, differently from a conventional EGR, the engine needs to have no special intake and exhaust passage in communication with a gas storage chamber, or no intake and exhaust valve.
That is, with the engine 100, in the case that the engine has a plurality of cylinders (the cylinders 110S, 120S, 130S, 140S), the construction of the cylinder head 110sh is not complicated, the fuel consumption can be improved, and nitrogen oxides (NOX) can be reduced.
In this preferred embodiment, the direction of burnt gasses discharged from the cylinder-sided passage into the inside of the cylinder is the direction along the periphery (for example, the periphery 110p) of the cylinder. Therefore, burnt gasses can be discharged to swirl along the periphery of the cylinder. That is, in the engine 100, unburned gasses in a quenching area (not shown) are reduced by the burnt gasses, and thus the amount of HC production can be reduced. Further, in the engine 100, the burnt gasses are discharged (refluxed) and swirled inside of the cylinder, and thus burnt gasses flowing near the periphery and a fresh fuel/air mixture flowing from the intake port can be stratified.
More specifically, the engine 100 improves an EGR rate (a value obtained by dividing an amount of burnt gasses refluxed into the inside of the cylinder by an amount of an intake air). Therefore, this contributes to a further improvement in the fuel consumption and cleanup of exhaust gas.
In this preferred embodiment, a period during which an exhaust valve of a certain cylinder section, for example, the exhaust valve 112 of the first cylinder section 110, opens overlaps a period during which an exhaust valve of a cylinder section other than the first cylinder section 110, specifically, the exhaust valve 132 of the third cylinder section 130, opens. That is, burnt gasses produced in the certain cylinder section are immediately supplied to another cylinder section. Therefore, this contributes to a further improvement in the fuel consumption and cleanup of exhaust gas.
The content of the present invention has thus far been disclosed with respect to the above-described preferred embodiment of the present invention. However, it should be recognized that no part of the descriptions and drawings of this disclosure limits the present invention. Those skilled in this art will appreciate that various alternative embodiments may be made or derived from the present disclosure.
For example, the direction of introducing a fluid, specifically a fuel/air mixture, into the inside of the cylinder via the intake port, is preferably along the periphery of the cylinder 110S viewing the cylinder 110S in its axial direction. The direction of introducing burnt gasses can be the same as a swirl direction of the fuel/air mixture in the case that the axis of the cylinder 110S is the rotational center. For example, in the first cylinder section 110 shown in
In this case, it is preferred that the period during which the exhaust valve opens overlaps a period during which the intake valve opens. With a modification in such a manner, a swirl flow of burnt gasses discharged inside of the cylinder can be enhanced.
While the period during which the exhaust valve of a certain cylinder section opens overlaps the period during which the exhaust valve of a cylinder other than the certain cylinder opens in the above preferred embodiment, both periods do not necessarily need to overlap.
In the above preferred embodiment, the direction of discharging burnt gasses from the cylinder-sided passage into the inside of the cylinder is along the periphery (for example, the periphery 110p) of the cylinder. However, the direction of discharging burnt gasses does not necessarily need to be along the periphery of the cylinder.
In the above preferred embodiment, the engine 100 preferably is an in-line four-cylinder engine. However, the engine 100 is not limited to the in-line four-cylinder engine, but can be an in-line six-cylinder engine, or a V-type eight-cylinder engine. Further, the engine 100 does not necessarily have to be an even number cylinder in-line engine. For example, the engine 100 can be a three-cylinder engine or a five-cylinder engine.
In the above preferred embodiments, the descriptions are made with the motorcycle 10 serving as an example. However, it is a matter of course that the present invention can be applied to vehicles other than a motorcycle, for example, an engine (a four-cycle internal combustion engine) carried on a four wheeled motor vehicle.
While preferred embodiments of the present invention have been described above, it is to be understood that variations and modifications will be apparent to those skilled in the art without departing the scope and spirit of the present invention. The scope of the present invention, therefore, is to be determined solely by the following claims.
| Number | Date | Country | Kind |
|---|---|---|---|
| 2007-006375 | Jan 2007 | JP | national |
