Valve opening mechanism

Information

  • Patent Grant
  • 6732686
  • Patent Number
    6,732,686
  • Date Filed
    Friday, August 31, 2001
    23 years ago
  • Date Issued
    Tuesday, May 11, 2004
    20 years ago
Abstract
The present invention is a valve opening mechanism which has been designed so as to be able to open an actuator pin (30), on which a stop (31) is provided that is through-mounted to slide freely facing in a vertical direction in relation to the top of a rocker arm (7) and which is restrained by the bottom of the rocker arm (7) tip at a specified uppermost position, and the engine valves (4), by pushing downward during the exhaust stroke of a rocker arm (7).
Description




TECHNICAL FIELD




This invention relates to a valve opening mechanism which is distinct from conventional valve opening mechanisms in that it is constituted so as to be capable of opening an engine valve with suitable timing by the means of a rocker arm.




BACKGROUND ART




The compression pressure release type of engine braking, which is constituted so that it releases pressure within a combustion chamber that has been raised by the movement of pistons through the opening of an exhaust valve in the proximity of top dead center compression, and magnifies engine braking power by diminishing the energy that drives the pistons downward in an expansion stroke, is generally known.





FIGS. 1 through 3

represent examples of the conventional compression pressure release type of engine braking. In

FIG. 1

, the number


1


identifies the cylinder,


2


the combustion chamber,


3


the piston,


4


the exhaust valve, and


5


the exhaust port, respectively, and they are configured so that the base extremity is thrown upward by a push rod


6


and both exhaust values


4


are pushed downward and opened through the use of the cross head by the tip of an inclining exhaust rocker arm


7


, and exhaust gas is scavenged from the combustion chamber


2


toward the exhaust port


5


.




Then, when both exhaust values


4


are pushed downward and opened through the use of the cross head


8


by the tip of the above-mentioned exhaust rocker arm


7


, the tip of the above-mentioned exhaust rocker arm


7


pushes downward on the master piston


12


provided in the upper portion of the housing


11


, a separate slave piston


14


in the upper part of the housing


11


is driven downward by the generation of pressure in the oil line


13


which protrudes into the interior of the above-mentioned housing


11


and, through the use of an actuator pin


15


installed on one side of the cross head


8


, an exhaust valve


4


on one side is positioned so that it can be pushed downward independently by the said slave piston


14


.




Namely, through the action of the master piston


12


in a separate cylinder


1


that constitutes an exhaust stroke, a cross linkage coinciding with the stroke timing is established by the oil line


13


between the slave piston


14


of the cylinder


1


and the master piston


12


such that the slave piston


14


in the cylinder


1


which is in proximity to top dead center compression is driven, and it is designed in such a way that operating oil


18


(engine oil) is supplied through the use of a solenoid valve


16


and a control valve


17


, which constitutes a means of supplying operating oil that switches back and forth between the sustaining and release of oil pressure in the said oil line


13


.




At this point, the solenoid valve


16


effects the supply of operating oil


18


by means of a control signal


20


from a control device


19


, and the control valve


17


functions as a check valve so that oil pressure in the above-mentioned oil line


13


is sustained when the solenoid valve


16


is in a open state, and also serves to release oil pressure in the above-mentioned oil line


13


when the solenoid valve


16


is in a closed state.




Namely, it is constituted so that, with the solenoid valve


16


, the supply of operating oil


18


is effected by the plate


22


and pin


23


pushing downward on the ball


24


when the coil


21


is in energized state, and the supply of operating oil


18


is blocked by the ball


24


being pushed upward by the spring


25


when the coil is in an unenergized state, and also so that, through the use of the control valve


17


, the spool


26


is pushed upward by oil pressure when the solenoid valve


16


is in an open state and the transport of operating oil


18


is effected only in the direction of the above-mentioned oil line


13


due to a ball


27


provided inside the said spool


26


, and oil pressure is released toward the relief outlet


29


by the spool


26


being pushed downward by the spring


28


when the solenoid valve


16


is in a closed state.





FIG. 2

illustrates a design configuration for multiple cylinders exemplified in the case of a tandem 6-cylinder engine. Only Cylinder #


1


(


1


), Cylinder #


2


(


1


), and Cylinder #


3


(


1


) are depicted, and they are constituted such that the opening action of the exhaust valve


4


in proximity to top dead center compression in Cylinder #


1


(


1


) is taken by the exhaust push rod


6


of Cylinder #


3


(


1


), the opening action of the exhaust valve


4


in proximity to top dead center compression in Cylinder #


2


(


1


) is taken by the exhaust push rod


6


of Cylinder #


1


(


1


), the opening action of the exhaust valve


4


in proximity to top dead center compression in Cylinder #


3


(


1


) is taken by the exhaust push rod


6


of Cylinder #


2


(


1


). More specifically, they are arranged so that the exhaust valve


4


on one side can be opened in proximity to top dead center compression by driving the slave piston


14


of each cylinder with the use of the oil line


13


by means of the action of the master piston


12


using the exhaust rocker arm


7


(not shown in

FIG. 2

) on the basis of the exhaust push rod


6


of each cylinder.




Furthermore, as


9


in the diagram is an inlet push rod and


10


is an intake valve, it is needless to say that the said intake valve


10


is opened by means of an intake rocker arm (not shown) which is moved at an angle by the inlet push rod


9


during an intake stroke.




Therefore, as the control valve


17


functions as a check valve and closes the oil line


13


if the solenoid valve


16


is opened by a control signal


20


from the control device


19


, in the event that Cylinder #


1


(


1


), Cylinder #


2


(


1


), and Cylinder #


3


(


1


), respectively, reach proximity to the pressure top dead center with a different timing, as is indicated in Diagram


3


, the master piston


12


is pushed downward by the exhaust rocker arm


7


with an upward thrust of the exhaust push rod


6


for the purpose of opening an exhaust valve


4


in a separate cylinder during an exhaust stroke, thus creating pressure in the oil line


13


. Since the slave piston


14


of the cylinder


1


in proximity to the pressure top dead center is driven and an exhaust valve


4


on one side is opened, compressed air from the combustion chamber


2


escapes into the exhaust port


5


and the creation of capacity to push the piston


3


downward during the next expansion stroke is lost, thus making it possible to take effective advantage of the braking capacity achieved in the compression stroke.




Moreover, in

FIG. 3

(identical for FIG.


9


and

FIG. 11

, to be referenced later), the vertical axis represents lift (lifting range) and the horizontal axis represents the angle of rotation of the camshaft in Cylinder #


1


, while the “Δ” figures in the diagram indicate top dead center compression in each cylinder, the curves in the solid lines indicate lift in the exhaust valve


4


in each cylinder, and the curves in the dotted lines indicate the lift in the intake valve


10


(in Cylinder #


1


, for example, a 0°˜180° angle of rotation of the camshaft constitutes a explosive stroke,180°˜360° an exhaust stroke, 360°˜540° an intake stroke, and 540°˜720° a compression stroke, while the phases are shifted with top dead center compression as the origin.)




If the solenoid valve


16


is closed by a control signal


20


from the control device


19


, oil pressure in the oil line


13


is released by the control valve


17


, and as pressure is not generated inside the oil line


13


, the slave piston


14


ceases to be driven and the exhaust valve


4


is opened by normal valve opening operation only during an exhaust stroke and no longer is opened in proximity to top dead center compression.




In implementing the use of this compression pressure release form of engine braking, especially in the case of an OHV type engine as illustrated in

FIG. 1

, the actuator pin


15


is through mounted on the side of the cross head


8


, facing in a vertical direction, and is configured in such a way that only an exhaust valve


4


on one side is opened by pushing the said actuator pin


15


downward with the slave piston


14


, but there is a problem with opening up only an exhaust valve


4


on one side in that it is difficult to achieve greater engine braking capacity without being able to release pressure within the combustion chamber more effectively.




Namely, the exhaust rocker arm


7


in an OHV type engine is moved at an angle by linking it with the vertical reciprocating motion of the exhaust push rod


6


through the use of a camshaft not shown in the diagram, so, for example, the movements of the exhaust push rod


6


in proximity to top dead center compression are disregarded and the exhaust rocker arm


7


is moved at an angle by the slave piston


14


, and as a result of this there are situations in which risk exists in that the linkage between the exhaust push rod


6


and exhaust rocker arm can end up being disconnected despite both exhaust valves


4


being opened, so the use of a structure in which the exhaust rocker arm


7


is not moved at an angle except during an exhaust stroke has been avoided.




The present invention is one which has been made with a view the aforementioned situation, and its object is to provide a valve opening mechanism which is designed in such a way that all engine valves that are opened by a rocker arm will be able to be opened separately without inclining a rocker arm.




DISCLOSURE OF THE INVENTION




The present invention is one that has been equipped with a rocker arm that activates to open by pushing the base extremity upward with a push rod and by pushing a engine valve downward with a tip at the time of its angular movement, and an actuator pin which is through mounted to slide freely facing in a vertical direction relative to the tip of the said rocker arm and fitted with a hook stop by which the bottom of the tip of the rocker arm is restrained at its designated top position, and which involves a valve opening mechanism characterized in that it has been constructed so as to enable the opening of engine valves by pushing downward on the said actuator pin during the exhaust stroke of the above-mentioned rocker arm.




However, if the actuator pin is pushed downward during a non-inclined motion of the rocker arm, the said actuator pin will slide in a downward direction against the tip of the rocker arm, and the engine valves will be opened, in an identical manner to that which occurs with a rocker arm, with the actuator pin being pushed downward to the same point as the tip of the rocker arm is being pushed down to during a normal valve opening operation.




Furthermore, when the rocker arm is moved at an angle by the push rod to perform a normal valve opening operation, the actuator pin is fixed in its designated top position due to the fact that a hook stop is held to the bottom of the tip of the rocker arm and, with the use of that fixed actuator pin, the engine valves are pushed downward and opened by the tip of the rocker arm.




It is additionally desirable in the present invention that the actuator pin is constituted by a pin base which, having an hook stop at its longitudinal direction midsection, and which is through-mounted to slide freely in the area above the said hook stop and faces in a vertical direction in relation to the tip of the rocker arm, is also formed in a spherical shape on its lower extremity, and by a tip which maintains contact with the spherically-shaped component on the lower extremity of the said pin base through the use of a spherical sheet and which has a flat tread that pushes downward on the engine valves beneath it.




If done this way, even if the pin base of the actuator pin is inclined by the angular movement of the rocker arm, the tip on its bottom oscillates reciprocally and the inclination of the above-mentioned pin base is permitted when the rocker arm is moved at an angle by the push rod to perform a normal valve opening operation. On this basis, the above-mentioned tip is kept in this very posture whereby it comes into satisfactory contact with the bottom of the flat tread surface that faces toward the engine valves, so as a result, a normal valve opening operation by means of a rocker arm can be reliably executed without any impediment through the use of an actuator pin that has been fixed in the top position.




It is further preferable in the present invention to provide a master piston that is set into motion by being thrown upward by the base extremity of the rocker arm, a slave piston that pushes downward on the actuator pin at the end of the rocker arm provided in the appropriate cylinder whenever it is connected to the said master piston through the use of an oil line and pressure is generated in the said oil line by the operation of the above-mentioned master piston, and a means of supplying operating oil that switches back and forth to sustain or release oil pressure in the above-mentioned oil line.




Therefore, if oil pressure in the oil line is sustained by a means of supplying operating oil, the master piston is thrown upwards by the base extremity of the said rocker arm and operates whenever the rocker arm is moved at an angle by the push rod. As a result of this, the slave piston is driven by the generation of oil pressure in the oil line, and the engine valves are opened by the downward push of the actuator pin on the end of a rocker arm provided in the appropriate cylinder.




Moreover, pressure is not generated inside the oil line if oil pressure in the oil line is released by a means of supplying operating oil, and thus the slave piston ceases to be driven even if the master piston is moved, only normal valve opening operation is accomplished by the rocker arm, and valve opening operation by the actuator pin ceases to be performed.











BRIEF DESCRIPTION OF THE DRAWINGS





FIG. 1

is a cutaway view showing prior examples.





FIG. 2

is a schematic diagram representing the alignments for multiple pistons in previous examples.





FIG. 3

is a graph illustrating the operating timing of the exhaust valves in FIG.


2


.





FIG. 4

is a cross-section diagram that illustrates the first example configuration of the present invention.





FIG. 5

is a schematic drawing illustrating the alignment for multiple pistons in the first embodiment of the present invention.





FIG. 6

is a magnified view in which a portion has been cut away to show the details of the actuator pin in FIG.


4


.





FIG. 7

is a magnified view in which a portion has been cut away to show another example of an actuator pin.





FIG. 8

is a schematic diagram illustrating the alignment for multiple pistons in the second example configuration of the present invention.





FIG. 9

is a graph representing the operating timing of the exhaust valves in each cylinder in FIG.


8


.





FIG. 10

is a schematic diagram illustrating the alignment for the multiple cylinders in the third example configuration of the present invention.




And

FIG. 11

is a graph depicting the operating timing of the intake valves in each cylinder in FIG.


10


.











BEST CONFIGURATIONS FOR EMBODIMENT OF THE INVENTION




The following description is made with reference to the drawings.




FIGS.


4


˜


6


show an embodiment of this invention which is based on an application of the compression pressure release engine brake described in FIGS.


1


˜


3


. Therefore, a presentation of the previously-described constituents using the same symbols is omitted here.




As shown in

FIG. 4

, as opposed to having the actuator pin installed so that it passes through one side of the cross head


8


, in this form of the invention the actuator pin


30


is installed so that it slides up and down relative to the tip of the rocker arm


7


, a slave piston


14


is disposed directly above the actuator pin


30


, and the actuator pin


30


is pushed down by the slave piston


14


so that exhaust valves


4


on both sides are opened via the cross head


8


.





FIG. 5

shows an example of an in-line 6-cylinder engine wherein the opening of the exhaust valve


4


of the first cylinder #


1


(


1


) near compression top dead center is done by the third cylinder #


3


(


1


) exhaust pushrod


6


; the opening of the exhaust valve


4


of the second cylinder #


2


(


1


) near compression top dead center is done by the first cylinder #


1


(


1


) exhaust pushrod


6


; the opening of the exhaust valve


4


of the third cylinder #


3


(


1


) near compression top dead center is done by the second cylinder #


2


(


1


) exhaust pushrod


6


; and the cylinder


1


slave pistons


12


and master pistons


12


are interconnected by hydraulic routes


13


so that the timing of the exhaust strokes for the other cylinders


1


is such that the operation of the master piston


12


follows the operation of the cylinder


1


slave pistons


14


near compression top dead center.




As shown in

FIG. 6

, the actuator pin


30


has a stop area


31


in the central area along its length and comprises a pin body


33


above it which is installed through and slides up and down in relation to the end of the rocker arm


7


, and which is formed with a rounded area


32


on its lower end, and this rounded area


32


on the lower end of the pin body is held so that it moves in a rocking motion with a rounded seat


34


interposed, and so that the pin body


33


pushes the exhaust valve


4


downward via the crosshead


8


by means of a flat area


35


on its tip


36


, and this stop area


31


stops movement at the desired upper limit at the bottom of the end of the exhaust rocker arm


7


.




A ring part


37


is inserted from the top of the rounded seat


34


of the top


36


, and this ring part


37


serves to hold the rounded area


32


of the lower end of the pin body


33


so it does not come out.




Also, although the stop area


31


of the actuator pin


30


is shown with an upward-reducing taper in the figure, it could equally well be formed as a flat ring around it.




When the solenoid valve


16


is opened by a control signal


20


from the control device


19


, the control valve


17


functions as a check valve, and the hydraulic line


13


is closed. Therefore, when each of the engine's cylinders


1


reaches the vicinity of pressure top dead center according to its own timing, by thrusting the exhaust pushrod


6


upward so that the exhaust valves


4


of the other cylinders


1


which are exhausting can open, the master piston


12


is pushed upward via the exhaust rocker arm


7


and pressure is generated in the hydraulic line


13


, the slave piston


14


of the cylinder


1


at compression top dead center follows and goes down, and each slave piston


14


causes the actuator pins


30


on the ends of the exhaust rocker arms


7


to be pushed down.




The actuator pin


30


which is pushed down by the slave piston slides down relative to the end of the exhaust rocker arm


7


, and at the same location as the location where the end of the exhaust rocker arm


7


is pushed down in a normal valve-opening operation, which is to say the same as when the actuator pin


30


pushes down the top of the crosshead


8


, wherein both exhaust valves


4


are opened so that the compressed air in the combustion chamber


2


escapes efficiently to the exhaust port


5


, and there is no force pushing downward generated by the piston


3


during the next compression stroke, enabling the effective use of braking force during the compression stroke.




The exhaust rocker arm


7


is tilted by the exhaust pushrod


6


and the actuator pin


30


is stopped by the stop area


31


on the bottom of the end of the exhaust rocker arm


7


when normal valve opening is performed, thereby fixing the actuator pin


30


in the upper limit position. The top of the crosshead


8


is pushed down to the end of the exhaust rocker arm


7


via the fixed actuator pin


30


, and both exhaust valves


4


are thus opened.




At this point, even though the pin body


33


of the actuator pin


30


is tilted by the tilting of the exhaust rocker arm


7


, the bottom end of the tip


36


slides correspondingly, allowing the tilt of the pin body


33


. As a result, a good contacting position is maintained for the flat bearing surface


35


of the tip


36


relative to the top of the crosshead


8


. Therefore, normal valve opening can take be performed by the exhaust rocker arm


7


with absolutely no impediment via the actuator pin


30


which is fixed at the upper limit.




With the solenoid valve


16


closed by a control signal


20


from the control device


19


, the hydraulic pressure in the hydraulic line


13


is released by the control valve


17


, and since there is no pressure generated in the hydraulic line


13


, the slave piston


14


does not follow, and a separate valve opening operation can take place near compression top dead center.




In the above configuration, therefore, other valve-opening operations can be performed near compression top dead center since both exhaust valves


4


are operated by the exhaust rocker arm


7


in the normal exhaust stroke without tilting the exhaust rocker arm


7


. Thus, the pressure in the combustion chamber


2


can efficiently escape, greater engine braking force can be obtained, and the problem of broken linkages in the connection area between the exhaust pushrod


6


and the exhaust rocker arm can be avoided.




The above explanation is an application to compression pressure release-type engine braking. However, as shown in

FIG. 8

, the invention can also be applied to an exhaust gas recycling device wherein each cylinder


1


#


1


˜#


3


are provided with both exhaust valves


4


which are opened in the inlet stroke by inlet pushrods


9


.




Specifically, a constitution which comprises a master piston


12


located directly above the base point of the inlet rocker arm (not shown) which is thrust upward by the inlet pushrod


9


, with the master pistons


12


being connected to slave pistons


14


of their own cylinders by means of hydraulic lines


13


, can be obtained in which both exhaust valves


4


operate during the inlet stroke.




In this form, cylinder #


1


(


1


), cylinder #


2


(


1


), and cylinder #


3


(


1


), respectively, as shown in

FIG. 8

, have inlet strokes taking place according to different timings, as shown in FIG.


9


. The inlet rocker arm is tilted by the upthrust of the inlet pushrod


9


to open the inlet valve


10


, thus lifting up the master piston


12


, and generating pressure in the hydraulic lines


13


. The slave piston


14


for this same cylinder


1


follows, opening both exhaust valves


4


via the actuator pins


30


. The exhaust gases are recycled from the exhaust port


5


to the combustion chamber


2


due to the pressure differential, and the combustion temperature in the combustion chamber


2


is lowered in the next power stroke, thereby reducing NO


x


.




Thus, when this sort of exhaust gas recycling device is used, since both exhaust valves


4


, which are opened by the exhaust rocker arm


7


in the normal exhaust stroke, can be opened by a separate operation during the normal exhaust stroke without tilting the exhaust rocker arm


7


, the exhaust gases in the combustion chamber


2


can be efficiently recycled, a more efficient abatement of NO


x


can be achieved, and failures in the linkage between the exhaust pushrod


6


and the exhaust rocker arm


7


can be avoided.




Also, this exhaust gas recycling device can be configured such as the one shown in

FIG. 10

, wherein the cylinders (


1


) #


1


˜#


3


are each provided with both exhaust valves


10


, and each cylinder's


1


exhaust pushrod


6


opens the exhaust valves


10


in the exhaust stroke.




Specifically, the actuator pin


30


is installed so it slides through in the up-and-down direction relative to the end of the inlet rocker arm (not shown), which is tilted by the inlet pushrod


9


. The slave piston


14


is located directly above the actuator pin


30


, and the master piston


12


is located directly above the base end of the exhaust rocker arm


7


, and the master piston


12


for each cylinder and the slave piston


14


for these same cylinders are connected by a hydraulic line


13


.




Cylinders


1


#


1


, #


2


, and #


3


in

FIG. 10

, respectively, have different exhaust stroke timings as shown in FIG.


11


. The exhaust rocker arm


7


is tilted by the upthrust of the exhaust pushrod


6


in order to open the exhaust valve, and as a result, the master piston


12


is pushed up and pressure is generated in the hydraulic line


13


. The slave piston


14


for each cylinder


1


follows, and both inlet valves


10


are opened by means of actuator pins


30


. Since a portion of the exhaust gas in the combustion chamber


2


is efficiently swept out toward the inlet port (not shown), the exhaust gas which is swept out toward the inlet port can be recycled for the next inlet stroke in the combustion chamber


2


, and the combustion temperature for the next power stroke is reduced NO


x


can be abated.




The valve opening mechanism of this invention is not limited to the forms described above. Although the above descriptions have been presented assuming a straight 6-cylinder configuration, the invention can equally be applied to V-type and other engines with varying numbers of cylinders. Also, not only opposed exhaust and inlet valve 4-valve engines, but the invention may also be applied to 2-valve engines in which a single exhaust valve and a single inlet valve are provided for each cylinder. Naturally, a variety of other changes can be made within the scope of the invention.




POSSIBILITIES FOR INDUSTRIAL USE




The valve opening mechanism described above is applicable for compression pressure release-type engine braking and exhaust gas recycling devices in automobile and other engines.



Claims
  • 1. A valve opening mechanism which has been equipped with a rocker arm that actuates to open by pushing a base extremity upward with a push rod and by pushing engine valves downward with a tip whenever it moves at an angle, and an actuator pin that is through mounted to slide freely facing in a vertical direction relative to the tip of the said rocker arm and equipped with a rocker hook stop by which the bottom of the tip of the rocker arm is restrained at a specific top position, and which is characterized in that the valve opening mechanism has been constructed so as to enable the opening of engine valves by pushing the said actuator pin downward during the exhaust stroke of the above-mentioned rocker arm.
  • 2. The valve opening mechanism set forth in claim 1, characterized in that the actuator pin has a pin hook stop component at its longitudinal midsection, a spherical shape on a lower extremity, a tip with a rounded seat which slides freely to maintain contact between the spherical shape and rounded seat.
  • 3. The valve opening mechanism set forth in claim 1 or claim 2, characterized in that the valve opening mechanism has been equipped with a master piston that operates by being thrown upward by the base edge of the rocker arm, a slave piston that opens the engine valves by pushing the actuator pin on the rocker arm tip provided in the appropriate cylinder downward whenever the slave piston is linked to the said master cylinder through the use of an oil line and pressure is generated in the said oil line by the action of the above-mentioned master cylinder, and a means to supply operating oil that alternates between sustaining and releasing oil pressure in the above-mentioned oil line.
PCT Information
Filing Document Filing Date Country Kind
PCT/JP99/00330 WO 00
Publishing Document Publishing Date Country Kind
WO00/45035 8/3/2000 WO A
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Number Name Date Kind
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5546914 Scheinert Aug 1996 A
5626116 Reedy et al. May 1997 A
5692469 Rammer et al. Dec 1997 A
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5803038 Ihara et al. Sep 1998 A
5857438 Barnard Jan 1999 A
5890469 H.ang.kansson et al. Apr 1999 A
Foreign Referenced Citations (1)
Number Date Country
60252113 Dec 1985 JP