JP3638632B2 - Engine valve gear - Google Patents

Description

[0001]
[Industrial application fields]
  The present invention relates to an engine valve gear.
[0002]
[Prior art]
  A valve operating device for an engine is for opening and closing an intake valve and an exhaust valve along a predetermined lift curve. This lift curve indicates the relationship between the lift amount of the intake valve and the exhaust valve and the crankshaft rotation angle (camshaft rotation angle). Conventionally, for example, the lift curve is generally indicated by a broken line in FIG. In the figure, the horizontal axis represents the camshaft rotation angle, and the vertical axis represents the lift amount or valve speed of the intake valve and exhaust valve. Both the conventional exhaust valve lift curve EX ′ and the intake valve lift curve IN ′ are symmetrical about the maximum lift cam angle θm ′, and the exhaust valve open side cam angle θEXO ′ = closed side cam Angle θEXC ′, intake valve open side cam angle θINO ′ = closed side cam angle θINC ′. From the lift curves EX ′ and IN ′, it can be seen that in the conventional valve operating apparatus, both the intake and exhaust valves have the maximum opening at the center of the valve opening period. It can also be seen that both the opening side and closing side average valve speeds are set to be the same.
[0003]
[Problems to be solved by the invention]
  Incidentally, in order to improve the engine output, it is necessary to improve the charging efficiency. For this purpose, it is effective to increase the intake valve opening area or the lift amount. However, even if the intake valve opening area is increased, there is a limit due to restrictions on the valve opening forming space determined by the cylinder bore diameter. Therefore, for example, if the intake valve opening is increased, the exhaust valve opening must be reduced, and there is a concern that the exhaust efficiency may be reduced. In addition, if the lift amount is increased, it becomes necessary to form a large relief at the top of the piston in order to prevent the valve heads of the intake and exhaust valves from interfering with the piston at the time of the above overlap, which is a limitation in securing the compression ratio. There's a problem.
[0004]
  Therefore, the applicant of the present application has an asymmetric lift curve in which the maximum lift position is biased toward the advance side or the retard side as a valve operating device that can improve intake efficiency and exhaust efficiency without increasing the valve opening and lift amount. Is developing. For example, in the case of an exhaust lift curve, the maximum lift position is advanced so that a high blowdown pressure can be obtained and exhaust efficiency can be improved while reducing the exhaust valve opening. And the filling efficiency can be improved.
[0005]
  In order to advance the maximum lift position and secure the same lift amount in the exhaust lift curve, it is necessary to increase the opening speed of the exhaust valve, which causes the exhaust cam lift to open. There is a concern that the moving distance of the contact point between the side portion and the lifter becomes large, and the exhaust lifter has a large diameter as it is. In order to solve this problem, it is effective to arrange the exhaust lifter so as to be offset so that the open side portion contacts the cam shaft.
[0006]
  However, if the lifter is disposed offset with respect to the cam shaft, a bending moment and a shearing force are applied to the lifter, which is disadvantageous in securing the strength of the lifter, for example, causing a problem in weight reduction of the lifter.
[0007]
  The present invention has been made in view of the above circumstances, so that the intake efficiency and exhaust efficiency can be improved without increasing the valve opening and lift amount, and the bending moment and shear force acting on the lifter can be reduced. An object of the present invention is to provide a valve operating device for an engine.
[0008]
[Means for Solving the Problems]
  According to a first aspect of the present invention, there is provided a valve operating mechanism for an engine provided with a valve opening / closing mechanism for opening / closing an intake valve and an exhaust valve along a predetermined lift curve, wherein the valve opening / closing mechanism is camped by a lifter mounted on a valve shaft. The exhaust cam lift is configured so that it is pressed by the lift, and the shape of the exhaust cam lift is such that the curvature 1 / Ro of the open side is substantially smaller than the curvature 1 / Rc of the close.And the cam angle θ of the open side exo Is the cam angle θ of the closed part exc SmallerBy setting so that the average valve opening speed of the exhaust valve is larger than the average valve closing speed, the exhaust valve lift curve is asymmetric with the maximum lift position biased toward the advance side, and the exhaust valve cam lift section ofThe sliding contact length between the open side portion and the exhaust valve lifter is larger than the sliding contact length between the closing side portion and the exhaust valve lifter.The lifter and the exhaust valve camshaft are offset from each other so that the lifter is displaced on the side where the open side portion and the exhaust valve lifter are in contact with each other.
[0009]
  According to a second aspect of the present invention, in the valve operating mechanism for an engine having a valve opening / closing mechanism for opening / closing the intake valve and the exhaust valve along a predetermined lift curve, the valve opening / closing mechanism includes a lifter mounted on the valve shaft. It is a direct acting type configured to be pressed at the cam lift, and the shape of the intake cam lift is such that the curvature 1 / Rc of the closed portion is smaller than the curvature 1 / Ro of the open portion.And the cam angle θ of the closed part inc Is the cam angle θ of the open side ino SmallerBy setting so that the average valve closing speed of the intake valve is larger than the average valve opening speed, the lift curve for the intake valve is made asymmetric with the maximum lift position biased to the retard side, and the cam lift for the intake valve PartThe sliding contact length between the closed portion and the intake valve lifter is greater than the sliding contact length between the open portion and the intake valve lifter.The lifter and the intake valve camshaft are offset so that the lifter is displaced on the side where the closed portion and the intake valve lifter are in contact.
[0010]
  Here, in each of the above-described inventions, to make the curvature of the open side portion substantially smaller than the closed side portion has the following meaning. That is, the cam head portion in the present invention is composed of a cam lobe following the base circle and a cam nose constituting the maximum lift portion, but in particular, the curvature in the cam lobe is not constant but continuously changes. Although the curvature of the open side portion is reduced as a whole, the curvature of the open side portion may be large when viewed locally. In addition, the meaning that the curvature of a closed side part is substantially smaller than an open side part is also the same.
[0011]
[Action]
  According to the valve operating apparatus for an engine according to the first aspect of the present invention, the exhaust valve lift curve or the intake valve lift curve has an asymmetrical shape in which the maximum lift position is biased toward the advance side or the retard side. By appropriately selecting an asymmetrical shape, it is possible to suppress a decrease in exhaust efficiency while reducing the exhaust valve opening and improve the filling efficiency.
[0012]
  And when making the lift curve asymmetrical, the lifter and the camshaft are offset so that the lifter is displaced to the side where the lifter comes into contact with the portion of the cam lift where the average valve speed is large. Therefore, it is possible to widen the movement range of the contact point between the cam lift and the lifter without increasing the lifter diameter, thereby increasing the valve lift speed and securing the necessary lift amount.
[0013]
  Also, when the lifter is offset with respect to the camshaft, the intake valve or exhaust valve is offset in the same direction as the offset lifter, so that the contact point between the lifter and the portion of the cam lift where the average valve speed is high Since the valve shaft is positioned so as to support the bending moment, the bending moment acting on the lifter can be suppressed or eliminated, and the disadvantage of the lifter strength can be avoided.
[0014]
  furtherSince the exhaust valve lift curve is asymmetric with the maximum lift position biased toward the advance side, the exhaust valve opens to the maximum opening when the combustion gas pressure is high during the explosion stroke, resulting in high blowdown pressure. As a result, combustion gas can be reliably discharged, and exhaust efficiency can be improved.
[0015]
  And in invention of Claim 1,The lifter and exhaust valve camshaft are offset so that the opener of the exhaust valve cam lift and the exhaust valve lifter come into contact with each other.SoAlsoClaim 2In this invention, the intake lifter is displaced to the closed side.LetTherefore, the valve lift speed can be increased by increasing the moving range of the contact point between the cam lift and the lifter without increasing the lifter diameter.The Furthermore, in the invention of claim 1, since the exhaust valve is offset on the same side as the exhaust valve lifter,Bending moment and shearing force acting on the lifter can be suppressed or eliminated.
[0016]
【Example】
  Embodiments of the present invention will be described below with reference to the accompanying drawings. 1 to 6 are views for explaining an engine valve operating apparatus according to an embodiment (first embodiment) of the invention of claims 1 to 7, and FIG. 1 is a front view of the engine of the present embodiment. 2 is a sectional front view of the valve operating device, FIG. 3 is a sectional side view of the exhaust valve portion, FIG. 4 is a sectional plan view showing the valve opening, FIG. 5 is a schematic diagram showing an exhaust cam lift, and FIG. FIG.
[0017]
  In the figure, reference numeral 1 denotes a water-cooled four-cycle four-cylinder five-valve engine. The engine 1 has a crankcase 3 and an oil pan 4 laminated and fixed on a lower joint surface of a skirt portion 2a of a cylinder block 2, and an upper joint surface. The cylinder head 5 is fastened with a head bolt, and a head cover 6 is mounted on the upper mating surface of the cylinder head 5.
[0018]
  Pistons 7 are slidably inserted into cylinder bores 2b arranged in parallel with the cylinder block 2, and each piston 7 is connected to a crank pin 9b of a crankshaft 9 via a connecting rod 8. Yes. The crankshaft 9 extends in the arrangement direction of the cylinder bores 2b.
[0019]
  A combustion recess 5a constituting a combustion chamber is formed in the cylinder block side mating surface of the cylinder head 5, and the combustion recess 5a has an axis X and a crankshaft of the cylinder bore 2b as shown in FIG. A center intake valve opening 10a positioned on a straight line perpendicular to the axis 9 and three side intake valve openings 10b, 10b positioned on the left and right sides of the center intake valve opening 10a; Two exhaust valve openings 10c and 10c are formed so as to be adjacent to the intake valve openings 10b and 10b.
[0020]
  Here, the center intake valve opening 10a, the side intake valve opening 10b, and the exhaust valve opening 10c are located substantially on the circumference along the inner peripheral surface of the cylinder bore 2b. The diameters d1, d2, and d3 of the valve openings 10a, 10b, and 10c are set to satisfy the relationship of d2> d3> d1.
[0021]
  The reason why the diameters of the valve openings 10a to 10c are set in the above relation is as follows. That is, the target is to introduce as much air as possible into the cylinder bore in the bore axis X direction from the portion near the cylinder bore axis X when viewed in the cam axis direction. For this purpose, the air is first positioned near the cylinder bore axis X when viewed in the cam axis direction. The side intake valve opening 10b is made as large as possible, and the center intake valve opening 10b is also set to have a relatively small diameter so as to be positioned as close to the bore axis X as possible. Further, in order to avoid interference with the side intake valve opening 10b having a larger diameter, the exhaust valve opening 10c has a smaller diameter than the side intake valve opening 10b. The reduction in exhaust efficiency due to the reduction in the diameter of the exhaust valve opening 10c is suppressed by making the lift curve asymmetric, which is a feature of the present invention, as will be described in detail below.
[0022]
  The center and side intake valve openings 10a and 10b are led out to the outside by a center intake port 11a and a side intake port 11b, respectively, and the merged intake port 11 of these ports 11a and 11b is opened on one side wall of the cylinder head 5. . Further, the exhaust valve opening 10 c is led out by an exhaust port 12 a, and the merged exhaust port 12 of these ports 12 a opens on the other side wall of the cylinder head 5.
[0023]
  The center and side intake valve openings 10a and 10b can be opened and closed by valve heads 13a and 13a 'of the center and side intake valves 13 and 13, and the exhaust valve opening 10c can be opened and closed by a valve head 14a of the exhaust valve 14. It has become. The valve shaft 13b of the intake valve 13 and the valve shaft 14b of the exhaust valve 14 extend obliquely upward so as to expand outward at a predetermined clamping angle.
[0024]
  A retainer 15 is detachably attached to the upper end of each intake valve 13 and the upper end of each exhaust valve 14. A valve spring 16 is disposed in a compressed state between each retainer 15 and a spring seat 5b formed on the cylinder head 5, whereby the valves 13 and 14 close the valve openings 10a to 10c. It is so energized.
[0025]
  An intake lifter 17 is attached to the upper end portion of the intake valve 13 so as to surround the upper portions of the retainer 15 and the valve spring 16, and the retainer 15 and valve spring 16 are attached to the upper end portion of the exhaust valve 14. An exhaust lifter 18 is attached so as to surround the upper part of the exhaust. The intake and exhaust lifters 17 and 18 are slidably guided and supported by guide holes 5 c formed in the cylinder head 5. These intake and exhaust lifters 17 and 18 are cylindrical ones whose upper ends are closed, and shims 17a and 18a arranged and fixed on the inner surfaces of the closed walls are in contact with the upper ends of the valve shafts 13b and 14b. Yes.
[0026]
  An intake camshaft 19 and an exhaust camshaft 20 are disposed above the intake lifter 17 and the exhaust lifter 18 in parallel with the crankshaft 9, and a bearing portion formed on the upper mating surface of the cylinder head 5 and It is rotatably supported by a mounted cam cap. Although not shown, the intake camshaft 19 and the exhaust camshaft 20 are connected to each other by meshing gears attached to the respective end portions, and any one of the camshafts is connected to the above-described camshaft. The crankshaft 9 is connected with a gear or a chain. As a result of the gear coupling, the intake camshaft 19 rotates counterclockwise in FIG. 2 and the exhaust camshaft 20 rotates clockwise in FIG.
[0027]
  Here, in the present embodiment, the intake and exhaust valves 13 and 14, intake and exhaust lifters 17 and 18 and intake and exhaust cam shafts 19 and 20 are arranged, and intake and exhaust cam lift parts 21 and 22 are shaped (cams). This point will be described in detail.
[0028]
  When viewed in the camshaft direction, the intake lifter 17 is disposed such that its axis c is parallel to the intake valve axis b and is perpendicular to the intake valve 13 with respect to the intake camshaft 19 as shown in FIG. It is arranged so that only A is displaced toward the cylinder bore axis X side. The intake camshaft 19 and the center and side intake valves 13 and 13 are arranged such that the camshaft axis a and the intake valve axis b intersect.
[0029]
  When viewed in the cam shaft direction, the exhaust lifter 18 is arranged such that its axis f is parallel to the exhaust valve axis e and is perpendicular to the exhaust valve 14 with respect to the exhaust cam shaft 20 as shown in FIG. Only B is disposed so as to be displaced toward the non-cylinder bore axis X side.
[0030]
  On the other hand, the exhaust valve 14 is arranged so as to be deviated from the exhaust camshaft 20 in a direction perpendicular to the exhaust lifter 18 by C in the direction opposite to the cylinder bore axis X. It is set larger than the unit quantity B.
[0031]
  Furthermore, when viewed in the direction perpendicular to the cam shaft, as shown in FIG. 3, the exhaust cam lift 22 and the exhaust valve 14 are not displaced, but the exhaust lifter 18 is displaced outward by D. . As a result, the thickness between the lifter guide holes 5c is secured, and the exhaust lifter 18 is rotated about its axis.
[0032]
  Here, when the exhaust valve 14, the exhaust camshaft 20, and the exhaust lifter 18 are offset, from the viewpoint of securing an ideal combustion chamber shape, the inclination angle and position of the exhaust valve 14 are first set. It is desirable to set the positions of the exhaust lifter 18 and the exhaust camshaft 20 according to the deviation amount with reference to the above. The same applies to the intake valve 13. On the other hand, if the position of the exhaust valve 14 is used as a reference, the interval between the cam shafts may not match the interval determined from the transmission gear diameter or the like, so the exhaust valve 14 and the exhaust lifter 18 are based on the position of the cam shaft. It is also possible to determine. In such a case, it is conceivable that the exhaust lifter 18 is close to the exhaust port side, causing a problem in heat load. In this case, it is effective to reduce the heat load by disposing the water cooling jacket 5d outside the exhaust lifter 18.
[0033]
  Further, the top surface T of the cam lift portion 21 of the intake camshaft 19 is formed so as to protrude from the base circle 19a to a height corresponding to the maximum lift amount, and is located on the front side in the rotational direction. 21a and a valve closing lift 21b positioned on the rear side in the rotational direction, and the cam profiles of both lifts 21a and 21b are asymmetrical. That is, the curvature radius Rc of the valve closing lift 21b is set to be larger than the curvature radius Ro of the valve opening lift 21a, and the cam angle θINC of the valve closing lift 21b is the cam of the valve opening lift 21a. The angle is set smaller than θINO. As a result, the intake valve 13 reaches a maximum opening degree at a lower average opening speed than the conventional symmetrical lift by rotation of the large cam angle θINO of the intake camshaft 19 and a higher average than the conventional one by rotation of the small angle θINC. Fully closed at the closing speed.
[0034]
  On the other hand, the top surface T of the cam lift portion 22 of the exhaust camshaft 20 is formed to project from the base circle 20a to a height corresponding to the maximum lift amount, and is located on the front side in the rotational direction. 22a and a valve-lifting head portion 22b located on the rear side in the rotation direction, and the cam profiles of both the head portions 22a and 22b are asymmetrical. That is, the curvature radius Ro of the valve opening lift 22a is set larger than the curvature radius Rc of the valve lift 22b, and the cam angle θEXO of the valve lift 22a is the cam of the valve lift 22b. It is set smaller than the angle θEXC. As a result, the exhaust valve 14 reaches a maximum opening degree at a higher average speed than the conventional symmetrical lift by rotation of the small cam angle θEXO of the exhaust camshaft 20, and a lower average than the conventional one by rotation of the large cam angle θEXC. Fully closed at speed.
[0035]
  Here, the valve lift heads 21a, 22a and the valve lift lifts 21b, 22b are each composed of a cam lobe portion following the base circles 19a, 20a and a cam nose portion near the top surface T, in particular. The radius of curvature of the cam lobe portion is not constant but changes substantially continuously. Accordingly, the radii of curvature Rc and Ro are not radii of curvature when viewed locally, but radii of curvature when averaged as a whole. The radius of curvature Ro usually takes a positive value, but includes a negative value. In addition, considering the case where the radius of curvature changes from positive to negative, from positive infinity to negative infinity, it seems that there is no continuity at first glance. We decided to use curvature instead of radius. Therefore, a large curvature radius means that the curvature is small.
[0036]
  Next, the function and effect of this embodiment will be described. First, the operation of the exhaust valve 14 will be described. As the crankshaft 9 rotates, the exhaust camshaft 20 rotates clockwise in FIG. When the piston 7 descends to near the expansion bottom dead center, the valve opening lift 22a of the exhaust cam lift 22 starts to slide on the upper surface of the exhaust lifter 18 at the slide contact C1 (see FIG. 5), and the exhaust valve 14 opens. Start (see lift curve EX in FIG. 6). Subsequently, when the piston 7 starts to rise and enters the exhaust stroke, and the exhaust camshaft 20 rotates at an angle θEXO from the sliding contact start position of the valve opening lift 22a, the top surface T of the exhaust cam lift 22 is on the upper surface of the lifter. The exhaust valve 14 is slidably contacted with the sliding contact Co and has a maximum opening. When the exhaust camshaft 20 further rotates, the valve closing lift 22b of the exhaust cam lift 22 starts to slidably contact the upper surface of the lifter, and the exhaust valve 14 begins to close. When the exhaust camshaft 20 rotates at an angle θEXC from the sliding contact start position (Co) of the valve closing lift 22b, the base circle 20a starts sliding, the exhaust valve 14 is fully closed, and the piston 7 is exhaust top dead center. After that, it begins to descend and enters the intake stroke. In this case, the sliding contact with the lifter 18 of the valve opening lift 22a of the exhaust cam lift 22 changes by D1 from C1 to Co, whereas the sliding contact with the lifter 18 of the valve lifting lift 22b is Only D2 from Co to C2 changes, and D1> D2.
[0037]
  In such an opening / closing operation of the exhaust valve 14, in this embodiment, the curvature radius Ro of the valve opening lift portion 22a of the exhaust cam lift portion 22 is set large, that is, the curvature is set small, and the cam angle θEXO is set narrow. Therefore, the exhaust lift curve EX has an asymmetric shape in which the maximum lift angle θm is shifted to the advance side. Incidentally, the conventional exhaust lift curve EX ′ has a symmetrical shape with the maximum lift angle θm ′ as the center. Therefore, the maximum lift angle θm of the exhaust valve 14 of the present embodiment is advanced from the conventional maximum lift angle θm ′, and reaches the maximum opening earlier than before. In this case, as the cam angle θEXO of the valve opening lift portion 22a of the cam lift portion 22 becomes narrower, the advance angle increases and the maximum opening degree is reached earlier.
[0038]
  Here, in FIG. 6, a curve VEX indicated by a one-dot chain line indicates a change in the speed of the exhaust valve 14 in the present embodiment, and a curve VEX ′ indicated by a two-dot chain line indicates a change in the speed of the conventional exhaust valve. As can be seen from the figure, in the case of the conventional exhaust lift curve EX 'that has a symmetrical shape, the valve speed at the time of valve opening and the valve speed at the time of valve closing are both the maximum speed and the average speed. The speed curve is also symmetrical. On the other hand, in the case of this embodiment, the maximum speed and the average speed of the valve speed when the valve is opened are larger than the valve speed when the valve is closed. Thereby, the maximum lift amount equivalent to the conventional one is secured while the maximum lift angle is advanced.
[0039]
  Next, the operation of the intake valve 13 will be described. As the crankshaft 9 rotates, the intake camshaft 19 rotates counterclockwise in FIG. When the piston 7 rises to near exhaust top dead center, the valve opening lift portion 21a of the cam lift portion 21 of the intake cam shaft 19 starts to slidably contact the upper surface of the intake lifter 17 and the intake valve 13 begins to open (FIG. 6). (See lift curve IN). Subsequently, when the piston 7 starts to descend and enters the intake stroke, the intake camshaft 19 rotates θINO from the sliding contact start position with the lifter 17 of the valve opening lift 21a, the top surface T of the cam lift 21 is lifted. The intake valve 13 is slidably in contact with the upper surface and has a maximum opening. When the intake camshaft 19 further rotates, the valve closing lift 21b of the cam lift 21 starts to slidably contact the upper surface of the lifter, and the intake valve 13 begins to close. When the intake camshaft 19 rotates θINC from the sliding contact start position of the valve closing lift, the base circle 19a starts sliding, the intake valve 13 is fully closed, and the piston 7 starts to rise after the suction bottom dead center. The compression process begins. The diameter of the base circles 20a and 19a is set so that a slight clearance is generated between the base circles 20a and 19a. Strictly speaking, they are not in sliding contact with each other, but are expressed as sliding contact for convenience of explanation.
[0040]
  In such an opening / closing operation of the intake valve 13, in this embodiment, the curvature radius of the valve opening lift portion 21a of the intake cam lift portion 21 is set to be small, that is, the curvature is set to be large, and the cam angle θINO is set to be wide. Therefore, the intake lift curve IN has an asymmetric shape in which the maximum lift angle θm is shifted to the retard side. Incidentally, the conventional intake lift curve IN ′ has a symmetric shape centered on the maximum lift angle θm ′. For this reason, the maximum lift angle θm of the intake valve 13 of the present embodiment is retarded from the conventional maximum angle θm ′, and becomes the maximum opening later than the conventional one. In this case, the larger the cam angle θINO of the valve opening lift portion 21a of the cam lift portion 21, the greater the retard angle, and hence the slower the maximum opening.
[0041]
  In the present embodiment, since the exhaust valve opening 10c is set to have a relatively small diameter, a larger total area of the intake valve opening can be secured, and the amount of air introduced can be increased as the total area of the intake valve opening increases. In order to increase the total area of the intake valve openings, the two side intake valve openings 10b are set larger than the one center intake valve opening 10a, so that a larger portion of the increased air is seen in the camshaft direction as cylinder bores. Accordingly, the air is introduced from the side intake valve opening 10b located near the axis X, so that a larger amount of air is introduced from the vicinity of the center of the cylinder bore in the direction of the cylinder bore axis X, and so-called forward tumble (vertical vortex) is likely to occur. .
[0042]
  Here, since the center intake valve opening 10a is located on the outer side of the cylinder bore as viewed in the cam shaft direction, the air introduced from the center intake valve opening 10a cancels the air introduced from the side intake valve opening 10b. There is a tendency to generate so-called reverse tumble. In this embodiment, since the center intake valve opening 10a is set to have a smaller diameter than the side intake valve opening 10b, the amount of air from the center intake valve opening 10a is relatively small, and the reverse tumble is suppressed. Further, since the center intake valve opening 10b is set to have a small diameter, the center intake valve opening 10a can be arranged close to the cylinder bore axis X side, so that the air flow from the center intake valve opening 10a is also the side intake valve opening 10b. From this point, the reverse tumble can be suppressed.
[0043]
  On the other hand, since the exhaust valve opening 10c is set relatively small in order to ensure a large total area of the intake valve openings, there is a concern that the exhaust efficiency may be reduced. In contrast, in the present embodiment, the maximum lift angle θm in the exhaust lift curve EX is shifted to the advance side, so that the exhaust valve 14 opens to the maximum opening when the combustion gas pressure is high in the explosion stroke. As a result, a high blowdown pressure is obtained. Accordingly, when the diameter d2 of the side intake valve opening 10b is set large as in the present embodiment, and the diameter d3 of the exhaust valve opening 10c is set relatively small in order to avoid interference with the side intake valve opening 10b. However, combustion gas can be reliably discharged, and exhaust efficiency can be secured. Moreover, since the blowdown pressure is high, the scavenging efficiency at the time of overlap is improved, and the filling efficiency is improved accordingly.
[0044]
Further, in the present embodiment, since the exhaust efficiency is high as described above, the exhaust lift curve EX of the exhaust valve 14 is moved by moving the exhaust lift curve EX to the retard side as a whole as compared with the conventional symmetrical lift curve EX '. It is possible to delay the opening start timing to near the expansion bottom dead center (refer to the lift curve EXo in FIG. 6). In this case, the expansion ratio is increased so that the combustion pressure sufficiently acts on the piston. The exhaust loss can be reduced by the amount discharged after the exhaust gas temperature is lowered.
[0045]
  In this embodiment, since the maximum lift angle θm of the intake lift curve IN is shifted to the retard side, when the piston 7 descends to near the bottom dead center of the intake stroke and the negative pressure in the cylinder bore increases. The opening degree of the intake valve 13 is maximized. Therefore, the intake flow velocity is improved, the inertia effect is enhanced, and the intake air amount is increased.
[0046]
  Further, in this embodiment, since the intake efficiency is high as described above, the intake valve 13 is closed by moving the intake lift curve IN to the advance side as compared with the conventional symmetrical lift curve IN ′. It is possible to advance the timing to near the bottom dead center of suction (see lift curve INo in FIG. 6), and in this case, blowback in the low speed rotation region can be prevented.
[0047]
  In this embodiment, the maximum lift angle θm of the exhaust lift curve EX is moved to the advance side, and the maximum lift angle θm of the intake lift curve IN is moved to the retard side. The lift amount L1 of the exhaust valve 14 and the intake valve 13 at the time of lap becomes smaller than the conventional lift amount L2, so that the clearance for avoiding interference with the exhaust valve 14 and the intake valve 13 formed at the top of the piston 7 is avoided. Can be reduced or eliminated, and as a result, the compression ratio can be increased.
[0048]
  Furthermore, in this embodiment, as shown in FIG. 6, since the maximum valve opening speed and the average valve opening speed of the exhaust valve 14 are made larger than the maximum valve closing speed and the average valve closing speed, the exhaust lift curve EX is made asymmetric. However, a lift amount equivalent to that of the conventional symmetrical lift curve EX ′ can be secured. As shown in the drawing, the valve opening speed and the valve closing speed of the intake valve 13 are symmetrical with respect to the exhaust valve speed with the exhaust top dead center as the axis of symmetry, and the positive and negative are reversed. As in the case of the valve, a lift amount equivalent to that of the conventional symmetrical lift curve can be secured.
[0049]
  Here, when the curvature radius Ro of the valve opening lift portion 22a of the exhaust cam lift portion 22 is set larger than the curvature radius Rc of the valve close lift portion 22b as in this embodiment, as shown in FIG. The contact point of the lift portion 22a with the upper surface of the lifter changes greatly from C1 to Co. When the camshaft axis and the lifter axis are crossed as in the prior art, the lifter diameter may be increased. Therefore, in the present embodiment, the lifter axis f is shifted from the axis d of the exhaust cam shaft 20 to the side where the valve opening lift 22a rotates, that is, the upstream side in the rotational direction of the exhaust cam shaft 20 (the right side of FIGS. 2 and 5). ), The lifter diameter may be set slightly larger than D1 + D2, as is apparent from FIG. Thus, without allowing the lifter to have a large diameter, it is possible to widen the allowable movement range of the contact point between the cam and the lifter, the valve lift speed can be increased, and the necessary lift amount can be ensured. Incidentally, when obtaining an equivalent lift curve without deviating the lifter position, the lifter diameter needs to be slightly larger than 2 × D1.
[0050]
  The points related to the movement distance of the contact point between the cam head and the lifter in the exhaust valve 14 are the same in the case of the intake valve 13, and the intake lifter 17 is displaced by A from the intake cam shaft 19, so that the intake air Without allowing the lifter 17 to have a large diameter, it is possible to widen the allowable movement range of the contact point between the cam lift 21 and the lifter 17, increase the valve lift speed, and secure the necessary lift amount. .
[0051]
  Further, when the maximum lift position of the exhaust lift curve EX is advanced to increase the valve opening speed and the exhaust camshaft 20 and the exhaust lifter 18 are deviated as in the present embodiment, the valve opening initial stage When the valve acceleration of the exhaust valve increases, the contact point of the exhaust cam lift 22 with the exhaust lifter 18 moves outside the axis f of the exhaust lifter 18 (on the side opposite to the cylinder bore axis, right side in FIG. 5). As a result, the exhaust lifter Bending moment and shearing force act on 18 and this is disadvantageous in securing the strength of the lifter.
[0052]
  Therefore, in the present embodiment, the exhaust valve 14 is arranged so that its axis e is displaced further outside the axis f of the exhaust lifter 18. Therefore, when the exhaust cam lift 22 is in contact with the exhaust lifter 18 on the outer side of the axis f of the exhaust lifter 18, the exhaust valve 14 is positioned so as to face the contact point. Generation of bending moment and shearing force can be suppressed, and disadvantages in securing the strength of the exhaust lifter 18 can be avoided.
[0053]
  FIG. 7 shows a modification in which the generation of the bending moment and the shearing force can be avoided more reliably. The same reference numerals as those in FIG. 2 indicate the same or corresponding parts. In this modification, the exhaust valve 14 is displaced from the exhaust camshaft 20 by the dimension C, and the radius of the valve shaft 14b of the exhaust valve 14 is set to the above-mentioned dimension C. Thus, the exhaust valve shaft 14b supports most of the movement range of the lifter contact point of the exhaust cam lift part 22 from below, and the bending moment and shearing force generated in the exhaust lifter 18 can be avoided more reliably.
[0054]
  In the above-described embodiment, the intake valve 13 is arranged so that the intake camshaft 19 and the axis intersect, but the intake valve 13, the intake camshaft 19, and the intake lifter 17 are also used to suppress the generation of bending moment. Deviation can be arranged. In this case, in FIG. 2, it is effective to arrange the intake valve 13 so that its axis b is located further on the cylinder bore axis X side than the axis c of the intake lifter 17, so that a bending moment is applied to the intake lifter 17. Occurrence can be suppressed or avoided.
[0055]
  Further, the valve opening start timing and the valve closing end timing can be changed by advancing or retarding the asymmetric lift curve in the above embodiment according to the operating state of the engine while maintaining its shape. FIG. 8 shows an example in which the intake lift curve is advanced according to the engine operating state. In the figure, the same reference numerals as those in FIG. 6 indicate the same or corresponding parts.
[0056]
  In the example of FIG. 8, the intake lift curve INo is advanced by θMOD to the lift curve IN when the engine rotational speed exceeds a predetermined speed. Various conventional valve timing variable mechanisms for advancing or retarding the lift curve have been proposed. For example, a conventionally known mechanism that changes the relative angle between the camshaft and the timing gear can be employed. is there.
[0057]
  In the above example, the intake lift curve INo has an asymmetric shape in which the maximum retoff angle θm is retarded from the maximum lift angle θm ′ in the conventional lift curve IN ′. The angle θMOD to be made may be smaller than the angle θSTD to be advanced in the case of the conventional symmetrical lift curve INo ′. Therefore, the burden on the timing variable mechanism described above can be reduced.
[0058]
【The invention's effect】
  According to the valve operating apparatus for an engine according to the first aspect of the present invention, the exhaust valve lift curve or the intake valve lift curve has an asymmetrical shape in which the maximum lift position is biased toward the advance side or the retard side. By selecting an asymmetrical shape as appropriate, there is an effect that the charging efficiency can be improved while reducing the exhaust efficiency while suppressing the exhaust valve opening to be small.
[0059]
  And when making the lift curve asymmetrical, the lifter and the camshaft are offset so that the lifter is displaced to the side where the lifter comes into contact with the portion of the cam lift where the average valve speed is large. Therefore, it is possible to widen the range of movement of the contact point between the cam lift and the lifter without increasing the lifter diameter, and this has the effect of increasing the valve lift speed and ensuring the necessary lift amount.
[0060]
  Also, when the lifter is offset with respect to the camshaft, the intake valve or exhaust valve is offset in the same direction as the offset lifter, so the contact point between the lifter and the portion of the cam lift where the average valve speed is high Since the valve shaft is positioned so as to support the bending force, the bending moment and the shearing force acting on the lifter can be suppressed or eliminated, and there is an effect that a disadvantage in the strength of the lifter can be avoided.
[0061]
  furtherSince the exhaust valve lift curve is asymmetric with the maximum lift position biased to the advance side, the exhaust valve opens to the maximum opening when the combustion gas pressure is high during the explosion stroke, resulting in high blowdown pressure. Thus, the combustion gas can be reliably discharged, and the exhaust efficiency can be improved.
[0062]
  And in invention of Claim 1,The lifter and exhaust valve camshaft are offset so that the opener of the exhaust valve cam lift and the exhaust valve lifter come into contact with each other.SoAlsoClaim 2In this invention, the intake lifter is displaced to the closed side.LetTherefore, the valve lift speed can be increased by increasing the moving range of the contact point between the cam lift and the lifter without increasing the lifter diameter.There is an effect. In the invention of claim 1, since the exhaust valve is offset on the same side as the exhaust valve lifter,This has the effect of suppressing or eliminating the bending moment and shear force acting on the lifter.
[Brief description of the drawings]
FIG. 1 is a front view of an engine including an apparatus according to an embodiment of the present invention.
FIG. 2 is a cross-sectional front view of the apparatus according to the embodiment.
FIG. 3 is a cross-sectional side view of an exhaust valve portion of the apparatus of the embodiment.
FIG. 4 is a cross-sectional plan view showing a valve opening of the above-described embodiment apparatus.
FIG. 5 is a schematic view of an exhaust cam lift portion of the above-described embodiment apparatus.
FIG. 6 is a view showing a lift curve of the above-described embodiment apparatus.
FIG. 7 is a cross-sectional front view showing a modification of the exhaust valve portion of the embodiment device.
FIG. 8 is a diagram showing a lift curve when a variable valve timing device is added to the embodiment device.
[Explanation of symbols]
1 engine
13 Intake valve
13b Intake valve stem
14 Exhaust valve
14b Exhaust valve shaft
17 Intake lifter
18 Exhaust lifter
21 Intake cam head
21a Lifting lift (open side of intake cam lift)
21b Lifting part for valve closing (closed part of intake cam lifting part)
22 Exhaust cam head
22a Lifting head for valve opening (open side of exhaust cam lift)
22b Lifting part for valve closing (closed part of exhaust cam lifting part)
EX Exhaust lift curve
IN intake lift curve
Ro radius of curvature of the open side
Rc Curvature radius of closed part

Claims (2)

In a valve operating apparatus for an engine having a valve opening / closing mechanism that opens and closes an intake valve and an exhaust valve along a predetermined lift curve, the valve opening / closing mechanism is configured to press a lifter mounted on a valve shaft at a cam head portion. The shape of the exhaust cam head portion is configured such that the curvature 1 / Ro of the open side portion is substantially smaller than the curvature 1 / Rc of the close side portion, and the cam angle θ exo of the open side portion. Is set to be smaller than the cam angle θ exc of the closed portion, so that the average valve opening speed of the exhaust valve is made larger than the average valve closing speed and the lift curve for the exhaust valve is biased toward the advance side. The open side portion of the exhaust valve cam lift and the exhaust valve lifter so that the sliding contact length between the closed side portion and the exhaust valve lifter is greater than the sliding length of the exhaust valve lifter. The lifter is on the side where the lifter for the valve contacts Coordinating as valve operating device for an engine is characterized in that the said lifter and the exhaust valve cam shaft offset arrangement. In a valve operating apparatus for an engine having a valve opening / closing mechanism that opens and closes an intake valve and an exhaust valve along a predetermined lift curve, the valve opening / closing mechanism is configured to press a lifter mounted on a valve shaft at a cam head portion. The shape of the intake cam head is configured so that the curvature 1 / Rc of the closed side portion is substantially smaller than the curvature 1 / Ro of the open side portion , and the cam angle θ inc of the closed side portion is By setting it to be smaller than the cam angle θ ino of the open side part, the average valve closing speed of the intake valve is made larger than the average valve opening speed and the lift curve for the intake valve is biased to the retard side An asymmetric type, and the closed side portion of the intake valve cam lift portion and the intake valve lifter have a sliding contact length greater than the sliding contact length of the open side portion and the intake valve lifter ; On the side that comes in contact with the intake valve lifter, There valve operating system for an engine, characterized in that the said lifter the intake valve cam shaft to deflect offset arrangement.

Images