JP3612875B2 - In-cylinder injection engine - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to an in-cylinder injection engine including an ignition plug and an injector that directly injects fuel into a combustion chamber for stratified combustion.
[0002]
[Prior art]
Conventionally, in a spark ignition type engine equipped with a spark plug, in order to improve fuel efficiency by stratified combustion, an injector is provided so as to face the combustion chamber, and fuel is directly injected and supplied from the injector into the combustion chamber. Internal injection engines are known. For example, an engine disclosed in Japanese Patent Laid-Open No. 6-81651 forms a combustion chamber between the upper surface of a piston fitted in a cylinder bore of a cylinder block and the lower surface of a cylinder head facing the piston, and the combustion chamber ceiling portion The intake port and the exhaust port are opened, the intake valve and the exhaust valve that open and close these ports are provided, and an ignition plug that faces the substantially central portion of the combustion chamber is provided. An injector is disposed in the cylinder so that the tip of the injector faces the combustion chamber from the vicinity of the peripheral edge of the combustion chamber.
[0003]
In this engine, the combustion chamber ceiling portion on the lower surface side of the cylinder head is a pent roof type in which the wall surface on the intake port opening side and the wall surface on the exhaust port opening side are inclined substantially symmetrically with the top portion interposed therebetween. The valve is arranged such that the valve axis is perpendicular to the wall surface on the intake port side and the wall surface on the exhaust port side, that is, both valve axis lines are inclined substantially symmetrically on both sides of the cylinder bore axis line.
[0004]
In addition, it is desirable to arrange the injector on the side of the intake port side of the combustion chamber in order to avoid the thermal influence from the exhaust side, and the structure in this case is shown in FIGS. In the example, an injector is arranged at the lower side of the intake valve side so that the tip of the injector faces the peripheral edge of the wall on the intake port opening side of the combustion chamber ceiling, while the intake port In order to avoid the valve shaft of the valve and the injector arrangement portion below the valve shaft, the upstream side extends upward from the valve shaft of the intake valve and is connected to the intake manifold above the cylinder head.
[0005]
[Problems to be solved by the invention]
In the engine, the combustion chamber is a pent roof type, and an opening portion of the intake port is arranged on one inclined surface of the ceiling portion, and the tip end portion of the injector is disposed on the outer peripheral side of the cylinder bore from the intake port opening portion. However, in such a combustion chamber structure, if the opening area of the intake port is increased, there is not enough space to face the tip of the injector. There is a problem that the opening area of the is reduced.
[0006]
In addition, the upstream portion of the intake port extends upward from the valve shaft of the intake valve. With such a port arrangement, it is difficult to generate a swirl (lateral vortex) in the combustion chamber, and turbulent flow is caused. In addition to being restricted such that the generation is limited to tumble, the intake manifold connected to the intake port protrudes above the cylinder head, so that there are inconveniences such as an increase in the overall height of the engine and hindering compactness.
[0007]
In terms of swirl generation, intake system layout, etc., it is desirable to arrange the upstream portion of the intake port so that it extends below the valve shaft of the intake valve. Since the valve axis of the intake valve is relatively largely inclined with respect to the cylinder bore axis, it is difficult to space the injector and the intake port below the portion where the valve axis of the intake valve is disposed. If an attempt is made to arrange the intake port, problems such as an increase in intake resistance occur by bending the intake port to avoid the injector.
[0008]
In view of the above circumstances, the present invention secures an injector mounting space on the side of the combustion chamber on the intake port side, and can also rationally arrange the intake port without causing an increase in intake resistance. An object of the present invention is to provide an in-cylinder injection type engine capable of effectively performing combustion.
[0009]
[Means for Solving the Problems]
In order to achieve the above object, the present invention provides an intake port and an exhaust port that form a combustion chamber between an upper surface of a piston disposed in a cylinder bore and a lower surface of a cylinder head facing the piston, and open to the combustion chamber. In a cylinder injection engine in which an intake valve and an exhaust valve that open and close the intake port and the exhaust port, an injector that injects fuel into a combustion chamber, and an ignition plug are disposed in the cylinder head These valves are arranged so that the inclination angle of the valve axis of the intake valve relative to the cylinder bore axis is smaller than the inclination angle of the valve axis of the exhaust valve, and the wall on the intake port opening side and the wall on the exhaust port opening side of the combustion chamber Each is formed so as to be orthogonal to the valve axis of the intake valve and the valve axis of the exhaust valve, and the fuel on the intake port opening side is formed. The injector is arranged in the lower part of the cylinder head in the chamber side, the portion between the injector and the intake valve axis, forming an intake port extending from the combustion chamber on the side upper portion of the cylinder head The first intake port for swirl generation and the second intake port for tumble generation are provided in parallel as the intake ports, and the downstream end portions of the first and second intake ports are connected to the combustion chamber. The incident angle is the same, and the second intake port is formed on the upstream side of this portion so as to be shifted above the first intake port, and an on-off valve linked to each cylinder is provided on the upstream side of the second intake port. Is.
[0010]
According to this configuration, in the combustion chamber ceiling on the lower surface side of the cylinder head, the wall surface on the exhaust port opening side is inclined to a certain extent, while the wall surface on the intake port opening side is smaller in inclination, below the end of this wall surface. Thus, a space for allowing the tip of the injector to face is secured. Thus, an injector mounting space is secured on the side of the cylinder head on the intake port side of the combustion chamber. In addition, since the inclination angle of the valve axis of the intake valve is small, a sufficient space for the intake port arrangement is obtained between the valve shaft arrangement part and the injector arrangement part of the intake valve. By forming the intake port so as to extend from the combustion chamber toward the upper side of the cylinder head, a port arrangement advantageous for reducing the intake resistance can be obtained.
[0011]
Also, A first intake port for generating a swirl and a second intake port for generating a tumble are provided in parallel. By Swirls and tumbles can be generated in the combustion chamber according to the operating state and the like.
[0012]
In particular, the incident angles of the downstream end portions of the first and second intake ports with respect to the combustion chamber are made the same, and the second intake port is shifted upward from the first intake port upstream from this portion. An on-off valve linked to each cylinder is provided upstream of the second intake port. By Effective swirl and tumble adjustment.
[0013]
In other words, in order to make the inclinations of the valve axes of both intake valves equal, the incident angles of the downstream end portions of both intake ports with respect to the combustion chamber are the same, but on the upstream side of these portions, both intake ports are moved up and down as described above. By shifting, the port arrangement suitable for swirl generation by the first intake port and tumble generation by the second intake port is obtained. In this case, since there is a sufficient space between the valve shaft arrangement portion and the injector arrangement portion of the intake valve as described above, such a port arrangement is possible. Further, since the upstream sides of both ports are shifted vertically, the cylinder-linked on-off valve is easily incorporated on the upstream side of the second intake port.
[0014]
In the engine of the present invention, the valve operating mechanism is DOHC in which both the cam shafts on the intake valve side and the exhaust valve side are arranged in parallel on the cylinder head, and the exhaust valve is defined as the height positional relationship between the cam shafts in the cylinder bore axis direction. The height of the side camshaft is set lower than the height of the intake valve side camshaft, and the exhaust valve side camshaft is driven by the crankshaft via the transmission means, and the intake valve side camshaft is driven by the exhaust valve side camshaft. Therefore, it is advantageous to reduce the overall height of the engine by driving through the interlocking means.
[0015]
That is, as described above, the camshafts have different heights corresponding to the difference in the inclination of the valve axis between the intake valve side and the exhaust valve side, but the exhaust valve side camshaft is the transmission means. Is driven by the crankshaft, the pulley of the transmission means is provided on the exhaust side camshaft which is lower than the intake side camshaft, and the engine height in this portion is kept low.
[0016]
Alternatively, the valve operating mechanism is DOHC in which both the intake valve side and exhaust valve side camshafts are arranged in parallel on the cylinder head, and the height of the exhaust valve side camshaft is determined as the height positional relationship between both camshafts in the cylinder bore axis direction. The intake valve side camshaft is driven by a crankshaft through a transmission mechanism, and the exhaust valve side camshaft is connected by an intake valve side camshaft via interlocking means. The camshaft drive system is configured such that the camshaft is driven, the engine is disposed in the engine room below the hood of the vehicle, the camshaft is placed horizontally and the exhaust valve side camshaft is the exhaust valve You may comprise so that it may be located in the vehicle rear side rather than a side cam shaft.
[0017]
In this way, the engine height is lower on the front side of the vehicle where the exhaust valve side cam is located than on the rear side of the vehicle where the intake valve side cam is located, and a form that can respond quickly to the front-falling bonnet line is obtained.
[0018]
Further, if the interlocking means between the two cam shafts is constituted by a gear, the distance between the cam shafts can be reduced, so that the inclination of the valve axis of the intake valve can be reduced to reduce the intake / exhaust valve This is advantageous when the clamping angle of the valve shaft is reduced.
[0019]
DETAILED DESCRIPTION OF THE INVENTION
Embodiments of the present invention will be described with reference to the drawings.
FIG. 1 is a cross-sectional view of a direct injection engine according to an embodiment of the present invention, and FIG. 2 is a schematic plan view of a combustion chamber portion. In these figures, 1 is a cylinder head installed on the cylinder block 2, 3 is a piston disposed in the cylinder bore 4 of the cylinder block 2, and burns between the upper surface of the piston 3 and the lower surface of the cylinder head 1. A chamber 5 is formed, and a concave portion constituting a ceiling portion of the combustion chamber 5 is provided on the lower surface side of the cylinder head 1 in this portion.
[0020]
The cylinder head 1 is formed with an intake port and an exhaust port that open to the combustion chamber 5. In this embodiment, two intake ports 6 and 7 and two exhaust ports 8 and 9 are formed for each cylinder. Yes. Each intake port 6, 7 is equipped with an intake valve 10, and each exhaust port 8, 9 is equipped with an exhaust valve 11, and each cam of the intake valve cam shaft 12 and the exhaust valve cam shaft 13 is provided. Thus, the intake valve 10 and the exhaust valve 11 are driven. Further, an injector 15 that directly injects fuel into the combustion chamber 5 and a spark plug 16 are attached to the cylinder head 1.
[0021]
The intake valve 10 and the exhaust valve 11 are different from each other in the inclination angles θ1 and θ2 of the valve axis with respect to the cylinder bore axis, and the inclination angle θ1 of the intake valve 10 is smaller than the inclination angle θ2 of the exhaust valve 11. The arrangement of the valves 10 and 11 is set, and the wall surface on the intake port opening side and the wall surface on the exhaust port opening side of the combustion chamber 5 are formed so as to be orthogonal to the valve axis line of the intake valve 10 and the valve axis line of the exhaust valve 11, respectively. Yes. Further, an injector 15 is disposed below the cylinder head 1 on the side of the combustion chamber on the intake port opening side, and intake ports 6 and 7 are formed between the injector 15 and the intake valve shaft.
[0022]
The specific structure of the combustion chamber 5 and the intake ports 6 and 7 is as follows.
[0023]
If the direction of the cylinder bore axis is the vertical direction, and the direction perpendicular to this (the direction of the mating surface of the cylinder head 1 and the cylinder block 2) is the horizontal direction, the valve axis of the exhaust valve 11 is relatively inclined with respect to the vertical direction. However, the valve axis of the intake valve 10 stands in a substantially vertical direction. And the intake port 6, 7 is opened on one side and the exhaust port 8, 9 is opened on the other side of the ceiling portion of the combustion chamber 5 across the top of the substantially center. 11 is an inclined surface orthogonal to the valve axis, that is, an inclined surface having a predetermined angle gradually approaching the cylinder head lower end surface (a mating surface with the cylinder block 2) from the center top of the combustion chamber, while the intake port opening side is on the intake port opening side. The valve 10 has a substantially horizontal plane orthogonal to the valve axis, and a vertical wall portion 18 is provided between the periphery of the surface on the intake port side and the lower end surface of the cylinder head. Thus, the shape of the combustion chamber as viewed in a cross section perpendicular to the camshafts 12 and 13 is substantially trapezoidal (see FIG. 1).
[0024]
The injector 15 is attached to the lower portion of the cylinder head 1 at the side of the intake port opening side portion of the combustion chamber 5, and the tip of the injector 15 faces the combustion chamber 5 from the vertical wall portion 18, and obliquely below. It arrange | positions so that a fuel may be injected toward. At least in the low speed and low load range, fuel is injected from the injector 15 in the latter half of the compression stroke due to stratified combustion. For example, the compression stroke injection is performed in the low / medium load range in the low / medium speed range. In the region, the injection timing is controlled by a control unit (not shown) so that fuel injection is performed in the intake stroke for uniform combustion.
[0025]
The injector 15 is preferably a high-pressure swirl injector. The high-pressure swirl injector generates a swirl in the spray 25 to promote atomization, and when the injection is performed at the latter stage of the compression stroke in which the pressure in the combustion chamber 5 becomes high, the spray angle becomes a narrow angle of 30 ° or less, When the injection is performed in the intake stroke where the pressure in the combustion chamber 5 is low, the spray angle is widened as compared with the latter injection in the compression stroke.
[0026]
Further, a recess 26 is formed on the upper surface of the piston 3 from the substantially central portion thereof to the vicinity of the peripheral portion of the combustion chamber on the side facing the injector 15 (exhaust side). The recess 26 is gradually recessed toward the front side in the injection direction from the injector 15, and the width in the direction orthogonal to the injection direction is larger than the injection width of the injector 15 in the late injection in the compression stroke. In order to correct the tendency of the combustion chamber volume to increase and the compression ratio to decrease due to the recess 26, a protrusion 27 protruding upward is provided on the intake side portion of the upper surface of the piston 3.
[0027]
The distance from the tip of the injector 15 to the combustion chamber end (the end of the recess 26 when the piston 3 is near the top dead center) facing the tip is from the injection start to the ignition timing in the compression stroke late injection. It is set larger than the spray reach distance in between. The spark plug 16 is disposed at substantially the center of the combustion chamber ceiling, and is disposed so that the ignition gap 16a at the tip thereof protrudes into the combustion chamber 5 and is interposed in the spray area from the injector 15. The distance from the tip of the injector 15 to the ignition gap 16a is set to be smaller than the spray reach distance.
[0028]
The intake ports 6 and 7 extend obliquely upward on the upstream side through a portion between the injector 15 and the intake valve shaft, and reach one side upper part of the cylinder head 1. An intake manifold 20 having intake passages 21 and 22 corresponding to these ports is connected to both the ports 6 and 7.
[0029]
Of the intake ports 6 and 7, the first intake port 6 is a swirl generating port, the second intake port 7 is a tumble generating port, and both intake ports 6 and 7 are combusted at the downstream end portion. Although the incident angle with respect to the chamber 5 is the same, the second intake port 7 is shifted upward from the first intake port 6 upstream of the throat portion. A swirl control valve (open / close valve) 23 for opening and closing the intake port 7 is provided in the upstream portion of the second intake port 7 or the intake passage 22 connected thereto. A swirl control valve 23 provided for each cylinder is linked via a common shaft 23a and is driven by an actuator (not shown).
[0030]
When the swirl control valve 23 is closed, a swirl (lateral vortex) is generated in the combustion chamber 5 by the intake air from the first intake port 6, and when the swirl control valve 23 is opened, its opening increases. The swirl is weakened and a tumble (vertical vortex) is generated by the intake air from the second intake port 7.
[0031]
The swirl control valve 23 is controlled according to the operating state by a control unit (not shown). For example, as control according to the engine load in the operation region in which the compression stroke injection is performed, the swirl control valve 23 is opened to some extent in order to avoid overspreading and bending of the spray due to swirl in the low load region. As the swirl is relatively weakened and the load increases, the opening of the swirl control valve 23 is reduced and the swirl is strengthened. Further, as control according to the engine speed in the operation region where the compression stroke injection is performed, as the speed increases, the control of the swirl control valve 23 is performed to reduce the swirl ratio so as to match the increase in the absolute flow velocity. The opening is increased.
[0032]
3 and 4 show a valve operating mechanism for driving the intake / exhaust valves of the in-cylinder injection engine. As shown in these drawings and FIG. 1 described above, the valve operating mechanism is a DOHC (double overhead camshaft) in which the camshafts 12 and 13 on the intake valve side and the exhaust valve side are arranged in parallel on the cylinder head 1. ).
[0033]
As for the height positional relationship between the cam shafts 12 and 13 in the cylinder bore axis direction, the height of the exhaust valve side cam shaft 13 corresponds to the arrangement of the intake and exhaust valves 10 and 11 as described above. It is set lower than the height of the cam shaft 12. That is, the lengths of the valve shafts of the intake valve 10 and the exhaust valve 11 are substantially the same, but the inclination of the exhaust valve shaft is larger than that of the intake valve shaft. The camshafts 12 and 13 are arranged in the height positional relationship as described above, corresponding to the positional relationship between the upper ends of the valve shafts.
[0034]
In this embodiment, the exhaust valve side camshaft 13 is driven by the crankshaft 30 via the transmission means, and the intake valve side camshaft 12 is driven by the exhaust valve side camshaft via the interlocking means. It is like that.
[0035]
More specifically, a crank pulley 31 provided at the front end of the crankshaft 30, a cam pulley 32 provided at the front end of the exhaust valve side camshaft 13, a timing belt 33 stretched over these, and an idler 34 The rotation of the crankshaft 30 is transmitted to the exhaust valve side camshaft 13 by the transmission means composed of the tensioner 35 and the like, and the cam pulley 32 has a pulley diameter twice that of the crank pulley 31 so that the exhaust valve The side camshaft 13 rotates with respect to the crankshaft 30 at a half speed. Further, gears 36 and 37 having the same diameter are provided in the vicinity of the front ends of the cam shafts 12 and 13 as interlocking means between the cam shafts. When these gears 36 and 37 mesh with each other, 13 rotate in the opposite directions at the same speed.
[0036]
In addition to the pulley 31, an auxiliary machine driving pulley 41 is provided at the front end of the crankshaft 30, and an alternator 43, a water pump 44 and the like are driven by an auxiliary machine driving belt 42 hung on the pulley 41. It has become so. In addition, a distributor mounting portion 45 is provided on the upper side of the cylinder head 1 on the side of the rear end portion of the exhaust valve side camshaft 13, and a distributor (not shown) attached to the mounting portion 45 is disposed on the exhaust valve side. Driven by the camshaft 13, a fuel pump 46 is attached to the side of the rear end of the intake valve side camshaft 12, and this fuel pump 46 is driven by the intake valve side camshaft 12 via a belt 47. It has come to be.
[0037]
The operation of the apparatus of the present embodiment as described above will be described next.
[0038]
At least in the operation region on the low-load, low-rotation side, fuel is injected from the injector 15 into the combustion chamber 5 in the latter half of the compression stroke, and stratified combustion is performed. In this case, in the present embodiment, the distance from the tip of the injector 15 to the combustion chamber end facing the injector 15 is made larger than the spray reach distance from the start of injection to the ignition timing in the latter half of the compression stroke, and the injector 15 Since the ignition gap 16a is interposed in the spray area from the center and the distance from the tip of the injector 15 to the ignition gap 16a is smaller than the spray reach distance, the spray is sprayed to an appropriate concentration around the ignition gap 16a. This prevents the fuel from adhering to the wall surface of the combustion chamber while ensuring the ignition stability. For this reason, HC emission is reduced, and fuel consumption and emission performance are improved.
[0039]
Further, a first intake port 6 for generating swirl and a second intake port 7 for generating tumble are provided, and a swirl control valve 23 provided for the second intake port 7 is controlled according to the operating state. By doing so, for example, the swirl ratio is increased toward the higher load side in the operation region where the stratified combustion is performed, and the swirl ratio is decreased toward the higher rotation side. By such control, stratified combustion is favorably performed.
[0040]
By the way, the injector 15 is disposed on the side of the intake port side of the combustion chamber 5 in the cylinder head 1 in order to avoid the thermal influence from the exhaust side, but the mounting space for the injector 15 is reduced due to the shape of the combustion chamber as described above. Secured. That is, the inclination angle of the valve axis of the intake valve 12 with respect to the cylinder bore axis is reduced, the surface on the intake port opening side in the ceiling portion of the combustion chamber is substantially horizontal, and the combustion chamber 5 is formed in a substantially trapezoidal cross section. The injector 15 is disposed so that the tip thereof faces the vertical wall portion 18 between the periphery of the surface on the intake port opening side in FIG. In this way, a space for mounting the injector 15 is secured without reducing the arrangement area of the intake port opening.
[0041]
The first and second intake ports 6 and 7 are effectively arranged in the space between the portion of the intake valve 10 where the valve shaft is disposed and the injector 15 positioned below the cylinder head 1. ing. In particular, since the inclination angle of the valve axis of the intake valve 10 with respect to the cylinder bore axis is made small, a space between the arrangement portion of the intake valve shaft and the injector 15 is widened. Since the intake ports 6 and 7 are formed so that the upstream side extends obliquely upward and the downstream side is bent gently to reach the combustion chamber 5, the intake resistance is sufficiently reduced.
[0042]
Further, the intake ports 6, 7 are shifted up and down so that the second port 7 is positioned above the first port 6 on the upstream side, so that the intake air flowing into the combustion chamber 5 from the first intake port 6. Has a relatively small angle with respect to the horizontal direction, and the intake air flowing from the second intake port 7 into the combustion chamber 5 has a relatively large angle with respect to the horizontal direction. Therefore, the first intake port 6 and the second intake port 7 are suitable for generating swirl and tumble, respectively. Further, a swirl control valve 23 is provided in an upstream portion of the second intake port 7 or an intake passage 22 connected thereto, and the swirl control valve 23 of each cylinder is connected by a common shaft 23a. Are shifted vertically from each other on the upstream side, so that the first intake port 6 does not get in the way when the swirl control valve 23 and the shaft 23a are attached.
[0043]
Moreover, since both the intake ports 6 and 7 are connected to the inlet manifold 20 on the side of the cylinder head 1, the intake port is located above the cylinder head as shown in the above-mentioned Japanese Patent Laid-Open No. 6-81651. Compared to the structure connected to the engine, the overall height of the engine can be lowered.
[0044]
Further, the valve operating mechanism includes both intake valve side and exhaust valve side camshafts 12 and 13 disposed on the cylinder head 1, and one of the camshafts is driven by the crankshaft 30 via the transmission means. At the same time, the camshafts 12 and 13 are interlocked via the interlocking means. In such a structure, particularly in this embodiment, the exhaust valve side camshaft 13 is driven by the crankshaft 30. As a result, the overall height of the engine can be lowered.
[0045]
That is, because the inclination of the valve axis with respect to the cylinder bore axis is larger in the exhaust valve 11 than in the intake valve 10, the upper end position of the valve shaft is lower in the exhaust valve 11 than in the intake valve 10 even if the valve shaft length is substantially the same. Correspondingly, the positional relationship between the cam shafts 12 and 13 is also lower on the exhaust valve side cam shaft 13 than on the intake valve side cam shaft 12. On the other hand, the cam pulley 32 in the transmission means has a relatively large diameter because the rotation of the camshaft is ½ of the rotation of the crankshaft 30. If the position of the cam pulley 32 is high, the upper end of the belt cover is located above the cylinder head 1. The cam pulley 32 is provided on the exhaust valve side camshaft 13 whose height position is low among the camshafts 12 and 13, but the cam pulley is provided on the intake side camshaft. The total engine height is lower than that provided.
[0046]
FIG. 5 shows another embodiment of the present invention. The engine of this embodiment is also an in-cylinder injection type engine in which fuel is directly injected into the combustion chamber 5 from the injector 15, and the shape of the combustion chamber and the arrangement of the injector 15 and intake / exhaust ports are the same as those of the first embodiment. Similarly, the valve operating mechanism is DOHC, one of the camshafts on the intake valve side and the exhaust valve side is driven by the crankshaft 30 via the transmission means, and both camshafts are gears, etc. It is the same as that of the first embodiment in that it is interlocked via the interlocking means. However, in this embodiment, the intake valve side camshaft 12 of the two camshafts is driven by the crankshaft 30, that is, the intake valve side camshaft 12 is provided with a cam pulley 32 '. The timing belt 33 is hung on.
[0047]
In this engine, the camshaft extends horizontally in the vehicle width direction in the engine room below the hood 50 of the vehicle, and the intake valve side camshaft 12 is positioned on the vehicle rear side with respect to the exhaust valve side camshaft. Is arranged.
[0048]
According to this embodiment, as described above, the intake valve side camshaft 12 is positioned higher than the exhaust valve side camshaft in response to the difference in the inclination of the valve axis of the intake valve 10 and the exhaust valve 11, and the intake valve By providing the large cam pulley 32 ′ on the side cam shaft 12, the belt cover largely protrudes upward on the side where the intake valve side cam shaft 12 is located, and the engine height of this portion increases. However, when this engine is placed horizontally in the engine room with the intake valve side camshaft 12 positioned on the vehicle rear side, the engine height is higher than that on the vehicle rear side where the intake valve side camshaft 12 is positioned. Since it becomes lower on the vehicle front side where the exhaust valve side camshaft is located, the shape conforms to the line of the bonnet 50 that descends forward, and the fit in the engine room is improved.
[0049]
That is, the structure of the present embodiment is suitable for a case where the engine is mounted horizontally on a vehicle in which the bonnet 50 is relatively large and descends forward. On the other hand, the structure of the first embodiment is suitable for a case where the engine is mounted vertically in a vehicle or a case where the engine is mounted on a vehicle having a relatively flat bonnet line.
[0050]
In addition, the specific structure of each part in the engine of this invention is not limited to the said embodiment, A various change is possible.
[0051]
For example, the interlocking means between the cam shafts on the intake valve side and the exhaust valve side is not limited to the gears 36 and 37, and a chain or the like may be used. However, if the gears 36 and 37 are used as in the illustrated embodiment, the distance between both camshafts can be reduced compared to a chain or the like. Therefore, even if the stagnation angle between the valve shafts of the intake and exhaust valves is reduced by reducing the inclination of the valve axis of the intake valve, no trouble is caused.
[0052]
Further, as a transmission means between the crankshaft and the camshaft, a chain may be used instead of the timing belt 33.
[0053]
【The invention's effect】
As described above, according to the present invention, in the direct injection engine, the intake / exhaust valve is arranged so that the inclination angle of the valve axis with respect to the cylinder bore axis is smaller than that of the exhaust valve, and the intake air in the ceiling portion of the combustion chamber The wall surface on the port opening side and the wall surface on the exhaust port opening side are formed so as to be orthogonal to the respective valve axis lines, and an injector is disposed below the cylinder head on the side of the combustion chamber on the intake port opening side. An intake port extending from the combustion chamber toward the upper side of the cylinder head is formed in a portion between the shaft and the injector mounting space on the side of the combustion chamber on the intake port side. Sufficient space for the intake port arrangement is obtained between the valve shaft arrangement part and the injector arrangement part. For this reason, the opening area of the intake port is not limited or the intake flow resistance is not increased, and it is difficult to generate swirl as in the case where the intake port is arranged upward from the intake valve shaft. An injector and an intake port for in-cylinder injection are effectively provided on the side of the cylinder head on the intake valve side without causing the disadvantage that the manifold is positioned above the cylinder head and the overall height of the engine is increased. It can be arranged.
[Brief description of the drawings]
FIG. 1 is a cross-sectional view of a direct injection type engine according to an embodiment of the present invention.
FIG. 2 is a schematic plan view of a combustion chamber of the engine and the vicinity thereof.
FIG. 3 is a plan view of the entire cylinder head of the engine.
FIG. 4 is a schematic front view showing a camshaft drive system of the engine.
FIG. 5 is a schematic front view showing another embodiment of the camshaft drive system.
[Explanation of symbols]
1 Cylinder head
3 Piston
4 Cylinder bore
5 Combustion chamber
6,7 Intake port
8,9 Exhaust port
10 Intake valve
11 Exhaust valve
12 Inlet valve side camshaft
13 Exhaust valve side camshaft
15 Injector
16 Spark plug
23 Swirl control valve
32 Cam pulley
33 Timing belt
36, 37 gear

Claims (4)

A combustion chamber is formed between an upper surface of a piston disposed in the cylinder bore and a cylinder head lower surface facing the piston, and an intake port and an exhaust port that open to the combustion chamber are formed in the cylinder head. In a cylinder injection engine in which an intake valve and an exhaust valve that open and close an exhaust port, an injector that injects fuel into a combustion chamber, and a spark plug are arranged in a cylinder head,
These valves are arranged so that the inclination angle of the valve axis of the intake valve relative to the cylinder bore axis is smaller than the inclination angle of the valve axis of the exhaust valve,
The wall surface on the intake port opening side and the wall surface on the exhaust port opening side of the combustion chamber are formed so as to be orthogonal to the valve axis line of the intake valve and the valve axis line of the exhaust valve, respectively.
An injector is arranged at the lower part of the cylinder head on the side of the combustion chamber on the intake port opening side, and an intake port extending from the combustion chamber toward the upper side of the cylinder head is formed between the injector and the intake valve shaft. And
As the intake port, a first intake port for swirl generation and a second intake port for tumble generation are provided in parallel, and the incident angle of the downstream end portions of the first and second intake ports with respect to the combustion chamber And the second intake port is shifted upward from the first intake port on the upstream side of this portion,
An in-cylinder injection engine characterized in that an open / close valve linked to each cylinder is provided upstream of the second intake port . The valve operating mechanism is DOHC in which both the intake valve side and exhaust valve side camshafts are arranged in parallel on the cylinder head, and the height of the exhaust valve side camshaft is taken into consideration as the height positional relationship of both camshafts in the cylinder bore axis direction. The height of the valve side camshaft is set lower than that, the exhaust valve side camshaft is driven by the crankshaft through the transmission means, and the intake valve side camshaft is driven by the exhaust valve side camshaft through the interlocking means. The in-cylinder injection engine according to claim 1 . The valve operating mechanism is DOHC in which both the intake valve side and exhaust valve side camshafts are arranged in parallel on the cylinder head, and the height of the exhaust valve side camshaft is taken into consideration as the height positional relationship of both camshafts in the cylinder bore axis direction. The intake valve side camshaft is driven by a crankshaft via a transmission mechanism, and the exhaust valve side camshaft is driven by interlocking means by an intake valve side camshaft. The camshaft drive system is configured as described above, and the engine is disposed in the engine room below the hood of the vehicle. The camshaft is horizontally placed extending in the vehicle width direction, and the intake valve side camshaft is the exhaust valve side camshaft. The in-cylinder injection engine according to claim 1 , wherein the in-cylinder injection engine is located on the vehicle rear side. Claim 2 or 3-cylinder injection type engine according to, characterized in that the interlocking means is constituted by a gear between the two camshafts.

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