Intake/exhaust valve assembly for an internal combustion engine

A simplified intake/exhaust valve assembly for an internal combustion engine which has a change-over operation of operative and inoperative state of the intake/exhaust valve is provided. The intake/exhaust valve assembly comprises a reciprocating valve having a valve stem and a valve head placed at a position at which an inlet/exhaust port opens into a power cylinder of the engine, to open and close the inlet/exhaust port in accordance with an axial movement thereof, a camshaft driven by a crankshaft of the engine, having a cam surface formed on the circumferential surface thereof, a cam follower having a first end associated with an end of the valve stem, a second end which forms a supporting point thereof, and a bearing surface contactable with the cam surface of the cam shaft, the cam follower being adapted to translate a rotation of the camshaft into the axial movement of the reciprocating valve so as to open and close the inlet/exhaust port in accordance with the rotation of the camshaft when the cam follower is made operative, and a support means comprising, a piston plunger having a head portion for supporting the second end of the cam follower, a cylindrical member for slidably receiving the piston plunger and having a hydraulic pressure chamber formed therein, and a retainer member for slidably receiving the cylindrical member, the cylindrical member being axially slidable in the retainer member between predetermined first and second positions in which the cam follower is made operative and inoperative respectively.

BACKGROUND OF THE INVENTION 
1. Field of the Invention 
The present invention relates to an intake/exhaust valve assembly for an 
internal combustion engine which is adapted to drive intake/exhaust valves 
provided to each power cylinder of an internal combustion engine, and more 
specifically to an intake/exhaust valve assembly which is capable of 
suspending the open and close operation of a part of intake and exhaust 
valves under a specific operational condition of the engine. 
2. Description of the Prior Art 
A type of internal combustion engine is known in which each of power 
cylinders is provided with a plurality of intake or exhaust valves, for 
example, 4 valves per cylinder or 6 valves per cylinder. 
In order to maintain a sufficient efficiency of the valve operation when 
the engine is operating at high speed, and to eliminate the blow-by of the 
mixture due to a so called "overlap" of the valve timing when the engine 
is operating at medium or low speed, it is preferable to provide an 
internal combustion engine of the type described above with the function 
of suspending the operation of a part of intake or exhaust valves when the 
engine is operating at medium or low speed. 
Such a type of intake/exhaust valve assembly is disclosed, for example, in 
Japanese Patent provisional publication No. 54-36415. 
In the case of the prior art valve assembly, however, there were several 
drawbacks that the construction of the assembly tends to be excessibly 
complicated, and therefore the durability thereof was not enough. 
SUMMARY OF THE INVENTION 
An object of the present invention is therefore to provide an 
intake/exhaust valve assembly for an internal combustion engine having the 
function of suspending the valve operation, which has a relatively simple 
stractural arrangement and therefore an improved durability. 
According to the present invention, an intake/exhaust valve assembly for an 
internal combustion engine including a crankshaft, a power cylinder, inlet 
and exhaust ports communicated to the power cylinder, comprises a 
reciprocating valve having a valve stem and a valve head placed in a 
position in which the inlet/exhaust port opens into the power cylinder, to 
open and close the inlet/exhaust port in accordance with an axial movement 
thereof, a camshaft driven by the crankshaft, having a cam surface formed 
on the circumferential surface thereof, a cam follower having a first 
portion associated with an end of the valve stem, a second portion which 
forms a supporting point thereof, and a bearing surface contactable with 
the cam surface of the camshaft, the cam follower being adapted to 
translate a rotational movement of the camshaft into the axial movement of 
the reciprocating valve so as to open and close the inlet/exhaust port in 
accordance with the rotation of the camshaft when the cam follower is made 
operative, and a support means comprising, a piston plunger having a head 
portion for supporting the second portion of the cam follower, a 
cylindrical member for slidably receiving the piston plunger and having a 
hydraulic pressure chamber therein, and a retainer member for slidably 
receiving the cylindrical member, the cylindrical member being axially 
slidable in the retainer member between predetermined first and second 
positions in which the cam follower is made operative and inoperative 
respectively. 
According to another aspect of the present invention, an intake/exhaust 
valve assembly for an internal combustion engine including a crankshaft, a 
power cylinder, inlet and exhaust ports communicated to the power 
cylinder, comprises a reciprocating valve having a valve stem and a valve 
head placed in a position in which the inlet/exhaust port opens into the 
power cylinder, to open and close the inlet/exhaust port in accordance 
with an axial movement thereof, a camshaft driven by the crankshaft, 
having a cam surface formed on the circumferential surface thereof, a cam 
follower having a first portion associated with an end of the valve stem, 
a second portion which forms a support point thereof and a bearing surface 
contactable with the cam surface of the camshaft, the cam follower being 
adapted to translate a rotational movement of the camshaft into the axial 
movement of the reciprocating valve so as to open and close the 
reciprocating valve in accordance with the rotation of the camshaft when 
the cam follower is made operative, and a support means comprising, a 
cylindrical support member including a support end for supporting the 
second end of the cam follower, the cylindrical support member having at 
least one protrusion projecting at substantially right angle to a 
longitudinal axis thereof, a retainer member for slidably and rotatably 
receiving the cylindrical support member, the retainer member having an 
opening portion for receiving the protrusion the cylindrical support 
member, the cylindrical support member axially slidable between 
predetermined first and second positions in which the cam follower is made 
operative and inoperative respectively, a spring member for applying a 
biasing force on the cylindrical support member for urging the same to the 
first position, and a positioning member associated with the protrusion of 
the cylindrical support member for moving the cylindrical support member 
along a longitudinal axis thereof between the first and second positions 
and holding the cylindrical support member at the second position against 
the biasing force whereby maintaining the inlet/exhaust valve inoperative. 
The foregoing and other objects and advantages of the present invention 
will become more clearly understood upon review of the following 
description taken in conjunction with the accompanying drawings.

DESCRIPTION OF A PREFERRED EMBODIMENT 
Reference is first made to FIG. 1 in which a portion of a cylinder block of 
an internal combustion engine provided with the intake/exhaust valve 
assembly is illustrated. 
As shown, an intake or exhaust valve body 10 is provided at a top portion 
of a power cylinder 3 which is formed in a cylinder block generally 
designated by 1. A valve head 11 of the valve body 10 is placed at a 
position at which an inlet or exhaust port 2 opens into the power cylinder 
3. A valve stem 12 of the valve body 10 is slidably received in a valve 
stem guide 13 which is fixed in a bore formed in the cylinder block 1 so 
that the valve head 11 opens and closes the inlet/exhaust port in 
accordance with an axial movement thereof. A valve spring 14 is held 
between a valve spring retainer 15 fixed to the valve stem 12 and a flange 
portion 16 formed integrally with the valve stem guide 13 so as to urge 
the valve body 10 in the direction to close the inlet/exhaust port 2. A 
top portion of the valve stem 12 is in abutment with an end 21 of a cam 
follower 20 which is supported at an another end 22 thereof which is 
formed into a hollow socket. A bearing surface 23 is formed on the upper 
face of the cam follower 20 so as to slidably contact with a cam surface 
26 formed on the circumference of a camshaft 25 which is driven by a 
crankshaft (not shown) of the engine. The rotational movement of the 
camshaft 25 is thus translated into a reciprocating movement of the valve 
body 10 by means of the cam follower 20 when the latter is held in an 
operative position. The end 23 of the cam follower 20 is held by a 
spherical head portion 33 of a piston plunger 30 which is received in a 
cylindrical support member 40. The piston plunger 30 has an axial passage 
31 which opens at the spherical head portion 33 and the lower end portion 
of the piston plunger 30 so as to communicate with a pressure chamber 35 
formed at the bottom of the cylindrical support member 40 and to supply a 
lubrication oil to the surface of the spherical head portion 33 of the 
piston plunger 30 which contacts with the hollow socket of the cam 
follower 20. An orifice 34 is formed in the side wall of the piston 
plunger 30 and communicates with an orifice 43 formed in the side wall of 
cylindrical support member 40. A ball valve 36 supported by a spring 37 in 
a retainer 38 is placed at the lower side of an orifice 32 disposed at the 
lower end of the piston plunger 30 to form a check valve. A spring 44 is 
placed in the pressure chamber 35 so as to urge the piston plunger 30 
upward. 
As shown in FIG. 2, the cylindrical support member 40 is further provided 
with a pair of protrusions 41 and 42 which substantially radially extends 
from a periphery of an upper opening portion thereof. 
The cylindrical support member 40 is axially slidably received in a 
retainer member 50 which is fixed to the cylinder block 1. A return spring 
51 is provided concentrically around the retainer member 50, between a 
flange portion formed on the retainer member 50 and the protrusions of the 
cylindrical support member 40 to urge the latter upward. 
As clearly shown in FIG. 3, the retainer member 50 is provided with a pair 
of recesses 52 and 53 each comprises three faces A, B, and C which form a 
step portion. At a position under a face D which is opposite to the 
upright face B, there is formed a latch recess which is engageable with 
the protrusion 41 or 42 of the cylindrical support member 40. 
As shown in FIG. 5, the protrusion 42 is provided with a round plate 
portion 45 which is engageable with a holder member 60 mounted on a shift 
rod 61 so as to rotate the cylindrical support member 40 around the 
longitudinal axis thereof with the reciprocating motion of the shift rod 
61. The cylindrical support member 40 rotates in the direction Q with the 
movement of the shift rod in the direction P shown in FIG. 5, for example. 
Furthermore, a pair of springs 62 and 63 are placed at both sides of the 
holder member 60 and supported by a pair of stop members 64 and 65 so as 
to apply a balanced biasing force on the holder member 60. 
An appropriate drive means is connected to the shift rod 61 to move the 
cylindrical support member 40 between first and second positions 
corresponding to the operative and inoperative states of the cam follower 
20, in accordance with the operational condition of the engine. The 
operation of the positioning of the cylindrical support member 40 will be 
described later more specifically. 
Returning to FIG. 1, the retainer member 50 is provided with a hydraulic 
pressure passage 54 which is communicable with the orifice 43 of the 
cylindrical support member 40 only when the latter is held in the raised 
(first) position for enabling the operation of the cam follower 20. The 
hydraulic pressure passage 54 is further communicated with a source of the 
hydraulic pressure via a conduit 55. 
The operation of the valve assembly according to the present invention will 
be described hereinafter. When the inlet/exhaust valve body 10 is to be 
made operative, the cylindrical support member 40 is placed at a position 
shown by the solid line in FIG. 5 by means of the operation of the shift 
rod 61. In this position, the protrusions 41 and 42 of the cylindrical 
support member are supported by the faces C of the recesses 52 and 53, and 
therefore the cylindrical support member 40 and the cam follower 20 are 
held at a raised position in which the cam follower 20 is swung by the 
rotation of the camshaft 25 to press the valve stem 12 against the 
resilient force of the valve spring 14 and open the valve. 
When the inlet/exhaust valve is to be made inoperative in spite of the 
rotation of the camshaft 25, the shift rod 61 is moved in the direction 
shown by the arrow P of FIG. 5 so as to rotate the cylindrical support 
member 40 in the direction shown by the arrow Q in FIGS. 4 and 5. 
Therefore, the protrusions 41 and 42 of the cylindrical support member 40 
are laterally moved to positions shown by dashed lines in FIG. 4. In this 
state, when the cam follower 20 is pressed by the cam surface of the 
camshaft 25, the cylindrical support member 40 is pressed down in the 
retainer 50 and the protrusions 41 and 42 reach the bottom of the recesses 
52 and 53. At this time, with the resilient force of the springs 62 and 
63, the protrusions 41 and 42 are moved into the latch recesses and held 
therein. In this way, the cam follower 20 is held in a lowered (second) 
position and no more transmit the movement of the camshaft 25 to the valve 
stem 12. FIG. 6 shows this inoperative state of the cam follower 20. 
To the contrary, if the shift rod 61 is moved in the direction opposite to 
the arrow P of FIG. 5, the protrusions 41 and 42 of the cylindrical 
support member 40 are moved laterally in the direction opposite to the 
arrow Q of FIGS. 4 and 5, and disengaged from the latch recesses. Then, 
the cylindrical support member 40 is raised by the resilient force of the 
return spring 51 and the protrusions 41 and 42 are further moved laterally 
in the direction opposite to the arrow Q, and held by the surface C. In 
this way, the cam follower 20 is replaced to the first raised position and 
the valve is made operative again. 
It should be noted that the durability of the valve assembly is prolonged 
as compared with the prior art mechanisms since the cam follower 20 is 
held in the lowered position against the resilient force of the return 
spring 51 in which the movement of the camshaft is not transmitted to the 
cam follower 20. Further, this position is maintained by a simple 
engagement of the protrusions 41 and 42 of the cylindrical support member 
in the latch recesses formed on the retainer member 50. 
In addition to the above feature, the supply of the hydraulic pressure is 
suspended by stopping the communication between the passage 54 in the 
retainer member 50 and the orifice 43 of the cylindrical support member 40 
when the cam follower 20 is held in the inoperative position. It is 
advantageous to eliminate the tendancy to raise the position of the piston 
plunger 30 that would cause a delay of the valve operation due to the 
depression of the piston plunger 30 before the complete rising of the 
cylindrical support member 40 during restarting of valve operation. 
Moreover, the movement of the shaft rod 61 is simplified by the provision 
of the springs 62 and 63 which ensures a smooth operation of positioning 
of the protrusions 41 and 42 on the surface C or in the latch recess 
formed on the retainer member 50. 
Turning to FIG. 7 an arrangement of valve assembly according to the present 
invention in an internal combustion engine will be explained. 
As shown, a camshaft 25 is mounted on a cylinder block of the engine and 
three cam followers 201, 202, and 203 are respectively associated with the 
camshaft 25. In this example, cam followers 201 and 203 are the type 
having operative/inoperative position as described above. The cam follower 
202 is supported in the conventional manner. A shift rod 61 is disposed in 
parallel to the camshaft 25 and two holder members 601 and 603 are 
slidably mounted on the shift rod 61. Each of the holder members 601 and 
603 are provided with a balanced biasing force by two pair of biasing 
springs 621, 631 and 623, 633. End portions (round plate portions) 451 and 
453 of the cylindrical support members 401 and 403 are held between a pair 
of flange portions of the holder members 601 and 603 so that the 
cylindrical support members 401 and 403 are positioned at either of the 
operative or inoperative position in accordance with the axial 
displacement of the shift rod 61. Furthermore, a cam follower guide 100 
having guide portions 101, 102 and 103 is provided to prevent the swing 
movement of the cam follower around the top end of the valve stem and 
therefore no guide or holder member is required at the hollow socket 
portion of the cam follower 20. 
The shift rod 61, in this case, is connected to a piston member 70 received 
in a cylinder member 80 which forms a hydraulic pressure chamber 71 
therein. The hydraulic pressure chamber 71 is communicated with a source 
of hydraulic pressure (not shown) via a supply opening 72. This source of 
hydraulic pressure supplies the hydraulic pressure to the hydraulic 
pressure chamber 71 in accordance with the operational condition of the 
engine. Thus, the position of the piston member, therefore, the position 
of the shift rod 61 is maintained at a position in which the cylindrical 
support members 401 and 403 are operative when the engine speed is high, 
and at a position in which the cylindrical support members 401 and 403 are 
inoperative when the engine speed is medium or low. 
In addition, it is advantageous to reduce the manufacturing cost that 
single cam follower guide 100 is used for guiding a plurality of cam 
followers. 
Reference is now made to FIG. 8A through FIG. 8D in which various positions 
of the shift rod 61 and the holder members corresponding to various states 
of the operational modes of the assembly are illustrated. As shown in 
FIGS. 8A and 8B, the holder members 451 and 453 remain at its initial 
position immediately after the movement of the shift rod 61 by the piston 
member 70. However, the holder members 451 and 453 will be displaced at an 
appropriate timing in accordance with the resilient force of the biasing 
springs 621 and 623 as shown in FIG. 8C. Similarly, the movement of the 
holder members 451 and 453 is delayed when the shift rod 61 return its 
initial position as shown in FIGS. 8D and 8A. Thus, the changeover 
operation of the operative and inoperative state of the cam follower by 
means of the shift rod is made smooth by the operation of the biasing 
springs. 
It will be appreciated from the foregoing, that according to the present 
invention, the positioning of the cylindrical support member which is used 
for determining the operative or inoperative state of the cam follower 
readily and positively effects an axial displacement of a shift rod since 
the latch and release of the protrusion of the cylindrical support member 
in the latch recess is automatically executed with the aid of the movement 
of the end of the cam follower which receives a pressure from the cam 
surface of the camshaft. 
Above, a preferred embodiment of the present invention has been described. 
It is to be noted, however, that the foregoing descriptions are for 
illustrative purpose only, and numbers of modifications are possible to 
those skilled in the art, and the scope of the present invention is 
limited by only appended claims.