Decompression system for engine

Information

  • Patent Grant
  • 6343579
  • Patent Number
    6,343,579
  • Date Filed
    Tuesday, October 12, 1999
    25 years ago
  • Date Issued
    Tuesday, February 5, 2002
    22 years ago
Abstract
A push rod operated multi-valve V-type engine particularly adapted for use in motorcycles or like vehicles and which engine is air cooled. The engine employs a very simplified construction and overhead valve actuating mechanism utilizing push rods. The push rods are contained within push rod tubes formed at one side of the engine that provide a neat appearance and ease of servicing without adversely affecting the air cooling. A composite cylinder head construction is employed, as well as an improved lubricating system for the pair of driven camshafts. Furthermore, a decompression system is incorporated in the valve actuating mechanism to lower the compression ratio so as to facilitate starting.
Description




BACKGROUND OF THE INVENTION




This invention relates to an internal combustion engine and more particularly to an improved decompression device for such engine.




As is well known, it is desirable to maintain a relatively high compression ratio for engines. By utilizing high compression ratios, greater specific output can be obtained. One disadvantage, however, with use of high compression ratios is that starting of the engine becomes more difficult. If electric starting is employed, the starter motor must be larger and more powerful as must be the drive between the starter motor and the engine. Where manual starting is utilized, the problems of high compression ratios are even greater.




There has been proposed, therefore, devices which operate so as to permit the engine to operate at a high compression ratio but which incorporate a device for reducing the compression ratio during starting. These decompression devices take many forms.




One way in which it is possible to reduce the compression ratio during starting is to open the exhaust valves for a brief period of time during the compression stroke. This will reduce the compression ratio and facilitate starting. The decompression device is then deactivated once the engine is started so that the maximum compression ratio can be enjoyed.




However, the provision of a mechanism for achieving this decompression is not as simple as it may appear. This is particularly true when the engine has multiple cylinders and multiple valves. It is basically desirable or even necessary to reduce the compression of all cylinders and this can be quite difficult and complex.




It is, therefore, a principal object of this invention to provide an improved and simplified arrangement for reducing the compression ratio than engine on starting.




It is a further object of this invention to provide an improved and simplified decompression device for engines having multiple valves and multiple cylinders.




SUMMARY OF THE INVENTION




This invention is adapted to be embodied in an internal combustion engine having a cam shaft with a plurality of cam lobes each of which cooperates with a follower for operating the valves of the engine. The cam shaft is formed with an axially extending bore in which an actuating cam member is supported for reciprocation. A plunger member is supported for reciprocation along an axis that is generally transversely disposed to this bore and which intersects at least one cam lobe in an area spaced from its tip portion. When the actuating cam member is moved in the bore, the plunger will be actuated and engage the follower and open the associated valve at a time during the stroke when the valve would normally be closed.











BRIEF DESCRIPTION OF THE DRAWINGS





FIG. 1

is a side elevational view of a motorcycle constructed in accordance with an embodiment of the invention.





FIG. 2

is a side elevational view of the engine looking in the opposite direction from FIG.


1


and with the push rod covers either partially or completely removed and other portions broken away to show the valve operating mechanism.





FIG. 3

is a cross-sectional view taken generally along the line


3





3


of FIG.


2


.





FIG. 4

is an enlarged view showing the valve operating mechanism associated with one of the cylinder heads with the main cylinder head component being shown in phantom.





FIG. 5

is a view showing the lower ends of the push rods the upper ends of which are shown in FIG.


4


and their driving relationship with the camshafts journaled within the crankcase.





FIG. 6

is a view looking in the same direction as

FIG. 5

but with the camshafts and crankshaft removed and showing more clearly the arrangement utilized to lubricate the camshaft operating mechanism.





FIG. 7

is a view looking in the same direction as

FIGS. 5 and 6

but shows the decompression mechanism associated with the engine.





FIG. 8

is a view looking in the same direction as FIG.


7


and showing the construction for the timing drive to interrelate the camshaft so that they will rotate in opposite directions from each other.





FIG. 9

is an enlarged cross-sectional view taken along a line


9





9


of FIG.


7


and shows the decompression actuating mechanism.





FIG. 10

is a view looking generally in the direction perpendicular to that of FIG.


9


and shows the interrelationship between the decompression mechanism for each cylinder bank.





FIG. 11

is an exploded view showing one of the cylinder head assemblies.





FIG. 12

is a top plan view of the cylinder head assembly with the rocker arm carrier not yet installed.





FIG. 13

is a is a view looking in the same direction as

FIG. 12

but shows the rocker arms journalling portion of the cylinder head assembly installed and with only the valve cover removed.





FIG. 14

is a view looking generally in the direction of the arrow


14


in FIG.


9


and shows the actuating device for the decompression system.





FIG. 15

is a cross sectional view taken generally along the line


15





15


in FIG.


14


.











DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS OF THE INVENTION




Referring first primarily to

FIG. 1

, a motorcycle is illustrated in side elevational view and is identified generally by the reference numeral


21


. The motorcycle


21


is powered by an internal combustion engine, indicated generally by the reference numeral


22


and which is constructed in accordance with an embodiment of the invention. The motorcycle


21


is shown as a typical environment in which the invention may be utilized.




The invention has particular utility in conjunction with motorcycle applications because the engine


22


should have a high specific output and also must be compact in construction but nevertheless be easy to start. Although this specific environment is shown as a typical environment with which the invention may be utilized, it will be readily apparent to those skilled in the art how the features of the engine


22


can be utilized with a number of other applications.




The motorcycle


21


is comprised of a frame assembly


23


upon which the engine


22


is suspended in a known manner. This frame assembly


23


dirigibly supports a front fork


24


on which a wheel


25


is rotatably journaled. A fender


26


covers this front wheel


25


. The steering of the vehicle is controlled by a handlebar assembly


27


that is fixed to the upper end of the front fork


24


in a manner well known in this art.




A rider's seat


28


is carried by the frame assembly


23


rearwardly of the engine


22


and above it. A fuel tank


29


for the engine is mounted on the frame


23


forwardly of the seat


28


.




Finally, a rear wheel


31


is journaled by the frame assembly


23


in a suitable manner and is driven by a transmission contained within a crankcase transmission assembly


32


of the engine


22


through a final drive which may comprise a driving belt covered by a cover


33


for driving a pulley


34


or sprocket fixed for rotation with the rear wheel


31


.




The construction of the engine


22


will now be described in more detail referring first primarily to

FIGS. 2 and 3

. In the illustrated embodiment, the engine


22


is of the V twin type and operates on a four cycle principle. To this end, the engine


22


is comprised of an engine body assembly including a cylinder block portion, indicated generally by the reference numeral


35


, which is formed with a pair of angularly related cylinder banks


36


and


37


that are disposed at a V angle to each other. These cylinder banks


36


and


37


are formed by cylinder barrels that are affixed to an upper portion of a crankcase member


38


which with the cylinder banks


36


and


37


completes the cylinder block portion


35


.




The crankcase member


38


defines a crankcase portion of the engine body that includes the combined crankcase transmission assembly


32


and rotatably journals a crankshaft


39


in any suitable manner.




Each cylinder bank


36


and


37


is formed with a respective cylinder bore


41


in which a piston


42


reciprocates. The pistons


42


are connected to the upper or small ends of connecting rods


43


in a known manner. The connecting rods


43


are journaled in side-by-side relationship on a throw of the crankshaft


39


as best seen in FIG.


3


.




A cylinder head assembly, indicated generally by the reference numeral


44


is affixed to each cylinder bank


36


and


37


by means that include threaded fasteners


45


. The cylinder head assemblies


44


are each made up of four major components. These comprise a main cylinder head member


46


, a camshaft carrier


47


, a cylinder head cover


48


and a valve cover


49


. These main components are shown in FIG.


11


and will be described in more detail later by reference to this and other figures.




Still continuing to refer primarily to

FIGS. 2 and 3

, the transmission assembly for driving the rear wheel


31


from the crankshaft


39


will now be described. As has been previously noted, this transmission assembly is contained in part in the combined crankshaft transmission assembly


32


.




Affixed to one end of the crankshaft


39


is a main drive gear


51


which is enmeshed with a driven gear


52


of a change speed transmission, indicated generally by the reference numeral


53


. The driven gear


52


is coupled via a selectively actuatable multiple disc clutch


54


to a primary shaft


55


of the change speed transmission


53


.




This primary shaft


55


carries a plurality of primary gears which are enmeshed with secondary gears that are carried on a secondary shaft


56


of the transmission


53


. By selectively coupling the gears on the primary and secondary shafts


55


and


56


to the shafts through a suitable shifting mechanism, it is possible to change the drive ratio between the crankshaft


39


and the secondary shaft


56


. The secondary shaft


56


thus, functions as the output shaft of the change speed transmission


53


.




An understanding of the details of the transmission


53


is not believed to be necessary to permit those skilled in the art to practice the invention. It should be readily apparent that the invention may be utilized in conjunction with any desired type of transmission.




The secondary transmission shaft


56


or output shaft carries a sprocket or toothed wheel


57


which is engaged with a drive belt


58


. This drive belt


58


is contained within a transmission case enclosed by a cover assembly


59


.




The drive belt


58


drives a further sprocket


61


that is coupled to a transmission output shaft


62


. A further drive sprocket or pulley


63


is affixed to the opposite end of this output shaft


62


. This belt drives the rear wheel sprocket


34


as previously noted.




The construction of the cylinder head assembly


44


will now be described by primary reference to

FIGS. 3

,


4


and


11


-


13


. As has been previously noted, the cylinder head assembly


44


is made up of four major components, the main cylinder head member


46


, the rocker arm carrier


47


, the cylinder head cover


48


, and the valve cover


49


. These components are preferably formed from light alloy materials, such as cast aluminum or aluminum alloys.




The main cylinder head member


46


is formed with a recess


64


in its lower surface which overlies the cylinder bore


41


and forms the combustion chamber of each cylinder bank


36


and


37


with the head of the piston


42


and with the cylinder bore


41


. In the illustrated embodiment, the cylinder head recess


64


is formed with four ports, two of which lie on the side of the engine toward the valley between the cylinder banks


36


and


37


and which comprise intake ports.




These ports are served and supplied with a fuel air charge by an induction system. This induction system includes carburetors


65


or other charge formers that are conveniently disposed between these cylinder banks


36


and


37


and which are associated with the intake passages of the respective cylinder head assemblies


44


. These intake passages are shown partially in phantom in FIG.


4


and are identified by the reference numerals


66


. These passages terminate in an outer surface


67


of each cylinder head member


46


and receive the respective carburetors


65


.




Poppet-type intake valves


68


are slidably supported in each cylinder head member


46


by means that include valve guides


69


. These valves


68


are urged toward their closed position in closing relationship to the intake ports, which appear in FIG.


4


and are identified by the reference numeral


71


by coil compression spring assemblies


72


. These spring assemblies


72


act against keeper retainer assembly


73


for holding the valve


68


in their closed position. The mechanism for opening the valve


68


will be described later.




On the side of the cylinder head recesses


64


opposite the intake ports


71


, there are provided exhaust ports. These exhaust ports are valved by poppet-type exhaust valves


74


which are also reciprocally mounted in the cylinder head members


46


by means of valve guides


75


. Coil compression spring assemblies


76


act against keeper retainer assembly


77


for holding the exhaust valves


74


in their closed position. These exhaust valves


74


are opened in a manner which will also be described shortly.




The exhaust ports in the cylinder head members


46


terminate in respective exhaust outlet openings


78


formed in the cylinder head members


46


and which are adapted to detachably received an exhaust system for discharging the exhaust gasses from the combustion chambers to the atmosphere. Since the exhaust system constitutes no part of the invention, it has not been illustrated and will not be described. Those skilled in the art will readily understand how the invention can be utilized with a wide variety of types of exhaust systems.




The four valve per cylinder cylinder head assembly


44


as thus far described is further complimented by a means of a dual ignition system. To this end, the cylinder head members


46


are each formed with a pair of tapped openings


79


that receive spark plugs


81


as best seen in FIG.


3


. These spark plugs


81


are fired by a suitable ignition system and will ensure rapid flame propagation and complete combustion of the fuel air charge that has been delivered to the combustion chambers from the carburetors


65


. At this point, it might be well to state that although the invention is described in conjunction with a carbureted engine, the principles of the invention can be equally as well utilized with engines having other types of charge formers, such as fuel injection systems.




The valve operating mechanism for operating the intake valve


68


and exhaust valves


74


for each cylinder bank will now be described by particular reference to

FIGS. 4-10

, although this valve operating mechanism also appears in other figures.




First, it should be noted that the crankcase member


38


is formed with an internal wall that has a central opening


82


through which one and of the crankshaft


39


extends. A timing gear


83


is affixed for rotation with this end of the crankshaft


39


by means that include a fastener assembly


84


and key arrangement so that the timing gear


83


will be driven at crankshaft speed. The wall of the crankcase member through which the crankshaft extends is formed with a cylindrical projection indicated in the drawings by the reference numeral


85


for reference purposes.




As best seen in

FIGS. 7

,


9


and


10


, the timing gear


83


is encircled by the projection


85


and is in this area enmeshed with a driven camshaft timing gear assembly, indicated generally by the reference numeral


86


. This timing gear assembly


86


is of the split gear type so as to take up backlash in the system. This assembly is held onto a cam driving shaft


87


by means of a threaded fastener


88


.




This shaft


87


penetrates through a cover


90


that forms a gear case with the wall projection


85


and there drives a first camshaft driving gear


91


which has a driving relationship with a first camshaft


92


which is associated with one of the cylinder banks


36


and


37


. In the illustrated figures, this is the cylinder bank


37


.




The driving gear


91


is also a split-type backlash take up type of gear and is drivingly coupled to a second camshaft driving gear


93


which is associated with a camshaft


94


for the remaining cylinder bank, i.e., the cylinder bank


36


. Because of this relationship between the driving gears


91


and


93


, these gears will rotate in opposite directions as seen in FIG.


8


. This is done for a reason which will become more apparent shortly.




The area above the crankcase member projection


38


adjacent each camshaft


92


and


94


and on the upper side thereof is formed with an opening that receives a tappet body


95


. Each tappet body


95


is formed with a pair of bores that receive, respectively, an intake tappet


96


and an exhaust tappet


97


for the respective cylinder banks. These tappets


96


and


97


are engaged by the intake and exhaust cam lobes


98


and


99


, respectively, of each camshafts


92


and


94


. Since the construction of each camshaft is basically the same, except for the fact that they rotate in opposite directions, the same reference numerals are applied to the cam lobes


98


and


99


and the tappet bodies


96


and


97


for each cylinder bank.




As has been noted, the engine


22


is air cooled and to this end, both the cylinder barrels


36


and


37


are formed with cooling fins


101


. These cooling fins


101


extend generally around the periphery of the engine body, but are partially interrupted on the sides adjacent the camshaft


92


and


94


so as to provide recesses through which push rods


102


and


103


for each cylinder bank extend. The push rods


102


are associated with the intake tappets


96


, while the push rods


103


are associated with the exhaust tappets


97


. These push rods


102


and


103


extend upwardly and in effect cross over each other slightly as seen in FIG.


2


. These push rods


102


and


103


are encircled by a protective tube in a manner which will be described shortly.




Referring now primarily to FIGS.


4


and


11


-


13


, the intake and exhaust valve push rods


102


and


103


, respectively, extend upwardly along the side of the respective cylinder barrels


36


and


37


to the cylinder head assemblies


44


. The upper end of each of these push rods


102


and


103


cooperate with respective rocker arms


104


and


105


that are supported for pivotal movement on rocker arm shafts


106


and


107


.




These rocker arm shafts


106


and


107


are journaled in bosses


108


and


109


, respectively, formed in the cylinder head top piece


47


. As may be best seen in

FIG. 12

, the rocker arms


102


and


103


pass through a central opening


111


formed in a downwardly extending guide portion


112


of the rocker arm carrier


47


.




The rocker arms


104


and


105


have follower portions


113


and


114


that define spherical sockets into which the ends of the push rods


102


and


103


extend. These extensions


113


and


114


are formed at one side of the rocker arm assemblies


104


and


105


. At the other ends thereof, the rocker arm assembly


104


has a pair of extending arms


115


and


116


that are engaged with the tips of the intake valves


48


for their actuation. An adjusting screw


117


is provided on only one of these rocker arm extensions, this being the extension


115


, so as to permit adjustment of the lash in the intake valve train.




In a similar manner, the rocker arm


105


has a pair of valve actuating portions


118


and


119


that cooperate with the tips of the stems of the exhaust valves


74


for their actuation. Again, only the rocker arm portion


118


carries an adjusting screw


121


for adjusting the lash in the exhaust valves.




As may be best seen in

FIG. 12

, the cylinder head member


46


has openings to receive the fasteners


45


that affix the cylinder head member


46


to the cylinder blocks


36


and


37


and this assembly to the crankcase member


38


. The rocker arm carrier


47


is suitably affixed to the cylinder head member


46


. The head cover


48


is then fixed to the upper side of the rocker arm carrier


47


and the valve actuating mechanism is then closed by the valve covers


49


.




As best seen in

FIGS. 2

,


3


and


12


, the cylinder blocks


36


and


37


have recesses formed in one side thereof which are indicated generally by the reference numeral


122


that appears in FIG.


12


. The push rods


102


and


103


extend through these recesses and are encircled by push rod tubes


123


. As seen in

FIG. 9

, the lower ends of these push rod tubes


123


are sealingly engaged with the tappet carrier member


95


that is fixed to the crankcase member


38


and thus provide a good seal and protection in this area.




In a like manner, the upper ends of these push rod tubes


123


are sealingly engaged within the projections


112


of the rocker arm carrier


47


as may be seen in

FIGS. 2 and 4

and thus, the push rods


102


and


103


are well protected, but there is a neat overall appearance to the engine. Also, the push rods


102


and


103


can be easily removed for servicing, as should be readily apparent.




A lubrication system for the camshafts


92


and


94


and particularly their point of engagement with the tappets


97


is provided. This arrangement may be best understood by reference to FIG.


5


.




As may be seen, the crankcase member


38


is provided with an oil gallery


124


that extends in the area between the rotational axes of the camshafts


92


and


94


and vertically upwardly therefrom between the tappets


97


. This oil gallery


124


is drilled with feeder ports


125


and


126


, respectively, which are directed toward the area where the lobes


98


and


99


of the camshafts


92


and


94


engage the respective tappets


97


.




It should be remembered that the camshafts


92


and


94


rotate in opposite directions as seen by the arrows in FIG.


5


. As a result of this, the lubricant that is sprayed by the feeder ports


125


and


126


will be engaged with the cam surfaces that are rotating into engagement with the follower portions of the tappets


97


. Therefore, lubricant will be carried by the rotation into this area so that there will be provided adequate and copious amounts of lubrication for the cam mechanism and the tappets


96


and


97


.




Finally, and as the main feature of the invention, the engine


22


is provided with a decompression mechanism for facilitating starting. This decompression mechanism is shown best in

FIGS. 9 and 10

with its actuating system being shown in

FIGS. 14 and 15

.




Referring first to

FIGS. 9 and 10

and as has been noted, there is a timing drive for driving the camshafts


92


and


94


from the crankshaft


39


at one half crankshaft speed. This timing mechanism is contained within a timing case formed by an outwardly extending flange


127


of the crankcase cover piece


90


. A timing case cover


128


is affixed to and encloses the timing gear drive and specifically the intermeshing gears


83


and


86


within this case, indicated by the reference numeral


129


.




Each of the camshafts


92


and


94


is formed with a respective bore


131


that receives a decompression actuating cam


132


. These cams


132


are engageable with lift plungers


133


that engage the exhaust tappets


96


. An actuating pin


134


extends through the outer end of the camshafts


92


and beyond the timing gear


86


within the case


129


. These actuating pins


134


are actuated by an actuating mechanism shown in

FIGS. 14 and 15

and identified generally by the reference number


135


. This mechanism


135


will be described shortly and when so actuated will move the cams


132


so as to urge the plungers


133


outwardly and lift the exhaust tappets


97


. This will, in effect, open the exhaust valves.




This is done during a portion of the compression stroke. As may be seen in

FIG. 9

, the pins


133


are generally aligned with the ends of the lift portions of the intake cam lobes


98


so that the exhaust valves will be opened at a time during the compression stroke and thus, relieve the pressure in the cylinder so as to make cranking and starting easier.




The actuating mechanism


135


will now be described by particular reference to

FIGS. 14 and 15

. The outer peripheral edge of the cover piece


128


journals an actuating shaft


136


and which shaft has a pair of actuator arms


137


which are juxtaposed to the ends of the push rods


134


.




The shaft


136


extends transversely outwardly beyond the cover


128


and into a further cover and mounting member


138


that is fixed to the cover


128


in a suitable manner. A solenoid actuator


139


is carried by this cover


138


and has a plunger portion


141


that cooperates with a follower arm


142


on this extending end of the shaft


136


.




When the actuator


139


is operated, it will rotate the shaft


136


so as to reciprocate the plungers


134


in the direction to lift the tappets


39


and provide the decompression of the engines during a portion of the compression stroke, as previously noted.




When the solenoid actuator


139


is deenergized, return springs that are trapped in the bores


131


and operate on the cam members


132


will return the plungers


134


to their normal engine operating non-decompression condition.




The solenoid actuator


139


may be operated either manually, if the engine is manually started, or may be operated simultaneously with operation of the engine starter motor. This starter motor is shown in FIG.


2


and is identified generally by the reference numeral


143


. This starter motor operates on the crankshaft


39


through a suitable drive mechanism. The starter motor


143


is juxtaposed to an alternator


144


which is also driven from the engine crankshaft


39


in a suitable manner so as to provide electrical power for the system and to charge a battery (not shown).




Thus, from the foregoing description, it should be readily apparent that the engine construction is quite compact and provides a very effective way for operating the multiple valves for the engine while providing a decompression system for starting of the engine. Of course, the foregoing description is that of the preferred embodiment of the invention and various changes and modifications may be made without departing from the spirit and scope of the invention, as defined by the appended claims.



Claims
  • 1. An internal combustion engine decompression system, said engine having a cam shaft with a plurality of cam lobes each of which cooperates with a follower for operating valves of said engine, said cam shaft being formed with an axially extending bore in which an actuating cam member is supported for reciprocation, a plunger member supported for reciprocation in said cam shaft along an axis that is generally transversely disposed to said axially extending bore and inclined thereto so as to intersect said cam shaft at a point closely adjacent at least one cam lobe in an area spaced from its tip portion to engage said follower at a point closely adjacent the area where said tip portion engages said follower, and a decompression actuator for moving said actuating cam member in said bore for actuating said plunger to engage said follower and open the associated valve at a time during the stroke when said valve would normally be closed.
  • 2. An internal combustion engine decompression system as set forth in claim 1 wherein the at least one cam lobe operates an exhaust valve for opening said exhaust valve during a portion of the compression stroke.
  • 3. An internal combustion engine decompression system as set forth in claim 2 wherein there is also a cam on the cam shaft for operating an intake valve.
  • 4. An internal combustion engine decompression system as set forth in claim 3 wherein the decompression actuator comprises an actuator shaft pivotal about an axis that is transverse to the axis about which the cam shaft rotates and which has an operating arm engaged with the actuating cam member.
  • 5. An internal combustion engine decompression system, said engine having a pair of cam shafts journalled for rotation about parallel axes, each of said cam shafts having a plurality of cam lobes each of which cooperates with a follower for operating valves of said engine, each of said cam shafts being formed with an axially extending bore in which a respective actuating cam member is supported for reciprocation, a plunger member supported for reciprocation in each of said cam shafts along an axis that is generally transversely disposed to its respective axially extending bore and which intersects at least one cam lobe of the respective cam shaft in an area spaced from its tip portion, and a common decompression actuator for moving each of said actuating cam members in its respective bore for actuating the respective of said plungers to engage the respective of said followers and open the associated valve at a time during the stroke when said valve would normally be closed, said decompression actuator comprising an actuator shaft pivotal about an axis that is transverse to the axes about which said cam shafts rotate and which has a pair of operating arms each engaged with the actuating cam member of the respective cam shaft.
  • 6. An internal combustion engine decompression system as set forth in claim 5 wherein the at least one cam lobe on each cam shaft operates an exhaust valve for opening said exhaust valve during a portion of the compression stroke.
  • 7. An internal combustion engine decompression system as set forth in claim 6 wherein there is also a further cam on each cam shaft for operating a respective intake valve.
Priority Claims (1)
Number Date Country Kind
10-289482 Oct 1998 JP
US Referenced Citations (5)
Number Name Date Kind
1439798 Crane Dec 1922 A
1604704 Madden Oct 1926 A
3511219 Esty May 1970 A
4440126 Abermeth et al. Apr 1984 A
4455977 Kuczenski Jun 1984 A