Specially shaped cam lobe angular movement system arround off¬ set from symmetry axis point.

The invention refers to a new system and a new method that provides the capacility to a specially shaped cam lobe to rota- te gradually arround a fixed point, located off set from symme¬ try axis, on a rotating shaft, in such a way that the symmetry axis will move gradually on an angular direction between an initial and a final position. This movement of the cam lobe allows the simultaneous change of all the operational characte- ristics of the respective valve of an internal Combustion Engi¬ ne and namely: a) The lifting of the valves b) Timing (phase) c) Duration of valve opening - closing.

The system has the significant advantage of achieving the above mentioned characteristic changes in a gradual manner through the gradual movement of the cam lobe.

BACKGROUND OF THE INVENTION It is well known that the cams of the internal combustion engine camshafts during the rotation of the camshaft serve the following purposes:

1. They move (open-close) the air intake and exhaust valves of the internal combustion engine. The lifting of the valves depends on the cam lifting.

2. The define the duration of opening-closing of the valves, which is achieved by the "angle" of the cam, in other words by the special form of the cam profile.

3. They provide the correct timing of the valves, which is the opening and closing of each valve at the proper moment rela¬ tive to the crankschaft position, achieved by the different cam positions on the camshaft.

A camshaft with fixed cams results in a specific operation - behaviour of the valves and consequently in a specific beha¬ viour of the piston Internal Combustion Engine.

Internal combustion engines equiped with conventional fixed cam camshafts have the disadvantage of showing the maximum tor¬ que and power at a specific RPM number. When the internal combu¬ stion engine is therefore functioning in other RPM numbers,than

the above mentioned ones, the torque or the power of the engine is not satisfactory.

Systems that would reduce the above mentioned disadvantages, have been tested in a very small scale so far, and only in spe- cific types of internal combustion engines. Such systems for example operate with camshaft systems with inclined fixed cams, where the entire camshaft slides back artd«. forth along the axis of the camshaft, increasing or decreasing respectively the lifting of the valve depending on the relevant position of the lifter on the inclined cam. Simultaneously the camshaft itself has also the ability to turn in some degree with respect to its initial position changing in this way the timing of the valves.

Other systems, like for example the VTEC system are using camshafts with more than one fixed cams of different liftings, angles or phases for each valve, cooperating for each separate operational case, with a system of multiple rocker arms.

The application of systems with camshafts sliding along their axis has the very serious disadvantage of the imperative need for modification in the whole design of the internal combu- stion engine, while in the case of "V" type engines or with the camshaft on one side the application is impossible, since the distance between the valve lifters is strictly limiting in allowing any sliding movement of the camshaft.

On the other hand systems requiring camshafts with special camform (e.g. inclined cam) , entirely different from the conven¬ tional cams, used in the market today, require also the use of extremely specialized equipment and machinery for the manufa¬ cturing, as well as for the reconditioning of the cams. There¬ fore for the time being, under the present conditions of the market of the conventional engines, these camshafts cannot have a wide use and their application is extremely limited.

The VTEC system has also limited application, since its application is not possible or extremely difficult in "V" type engines or in engines with the camshaft on one side. This is because of the small distance between the cams, which is the sour ce of serious problems in the complicated system of multi¬ ple rocker arms . Additionaly the application of such a system requires not only the design and manufacture of a totally new

camshaft, but also the design and manufacture of a totally new cylinder head in which the multiple rocker arm system will be fitted. It is important to note at this point, that this system is impossible to operate correctly on very high valves of RPMs 5 due to the inertia of the multiple rocker arms at these high velocities.

Refering to the invention with Patent No US005161429A which describes a variable cam moving in an angular direction arround a point located on the symmetry axis, we observe that apart

10 from the complexity of the design and the use of specially sha¬ ped cooperating components for the faultless operation, the abo¬ ve mentioned invention allows the possibility of change only of the valve timing (.phase change and valve opening-closing time duration change). , where as it has no ability to change the

^5 lifting of the cam (and consequently of the valve) .

Refering to the invention with patent No.DE 42 22 477 A1 which describes a variable cam which operates whether with movable segment of the cam or with the combination of fixed movable segment, we observe that it can change only the lifting

20 of the cam and can not offer significant ability in simultaneous gradual change of the lifting as well as of the valve timing (phase, opening-closing duration) .

The present invention through the gradual angular movement of the specially shaped cam lobe arround a point, located off-

25 set from symmetry axis results in the simultaneous gradual change of the lifting as well as the timing (phase, opening- closing duration) of the respective valve.

The present invention has as prerequisite a longitudinal rotating shaft equipped with the angular movement system of

30 the specially shaped cam lobe, whose general idάmentions (e.g. diameter, bearing points etc.) remain unchainged in relation to the dimentions of the conventional camshaft that was part of the internal combustion Engine, and does not require changes in any other basic mashine elements of the Engine (e.g. cylin-

35. derhead) , it is also manufactured and reconditioned by exactly the same mashinetools that are used for the-conventional cam¬ shafts and it- is of general use in all the piston internal combustion Engine types.

In short this invention can be easily applied to all piston internal combustion Engines with no need for any modification.

In addition this system can be used in cooperation with fixed cams. The present invention improves the operation and performa¬ nce of the engine in general and more specifically it offers: a) The highest possible performance and efficiency of the engine in the whole operational RPM range without any compro¬ mise. b) Increase in power output. c) Lower fuel cousumption and pollution reduction. d) Reliability and simplicity. e) Easy mounting and removal of the cam lobe.

BRIEF DESCRIPTION OF DRAWINGS The following description of the drawings wherein like numerals are used to designate like parts of the specific forms embodied in spirit and essential characteristics of this invention and to be considered in all respects as illustrative and not restrictive thereof. FIG.1. Is a front and side view of the cam lobe angular movement system with the camlobe in the initial position.

FIG.2. Shows views of the specially shaped cam lobe of the above mentioned system.

FIG.3. Shows front and side view of above mentioned system with the cam lobe in final position.

FIG.4. Shows views of the specially shaped transmission shaft to the above mentioned system.

FIG.5. Shows front and side view in cross section of the above mentioned system with the cam lobe in initial position. FIG.6. Shows front and side view in cross section of the above mentioned system with the cam lobe in its final position.

FIG.7. Shows views and cross sections of the rotating longitudinal shaft of the above mentioned system.

FIG.8. Shows a view of the above mentioned system with the cam lobe in the initial, final and intermediate position.

FIG.9. Shows views in cross section of the above mentioned system where the movement of the cam lobe is achieved hydrau- licaly through an incompressible fluid.

FIG.10. Shows a variation of the above mentioned system with the cam lobe in the initial and-the final position.

FIG.11. Shows views and cross sections of the several parts of this system. FIG.12. Shows with the help of diagrams the improvement of the operational characteristics of the valve.

DETAILED DESCRIPTION OF THE ILLUSTRATED EMBODIMENT Referring to FIG.s 1 to 8 we see an application of the cam lobe angular movement system consisting of: The specially shaped cam lobe (1) , the rotating longitu¬ dinal (.2) the specially shaped transmission shaft (3) and the balls (4) and (5) .

On one of the sides of the cam lobe we find the modulation (9) , which in cooperation with the respective modulation (10) of the rotating shaft (2) allows the support and conjunction of the cam lobe (1) on the shaft (2) while in the same time creates the joint, arround which the cam lobe is able to rotate.

The rotating shaft (2) has a hole (.8) drilled through the whole lenght, through which the lubrication mean is circu¬ lated for the lubrication of the shaft bearings . Inside this hole, the longitudinal transmission shaft C3) is able to move in both directions gradually, and which shaft on the longitu¬ dinal direction is grooved on the outer surface with an appro- priate number of grooves (14) (parallel or helical or any other type) , for the easing of lubricating mean circulation,it also has two modulations, (ramps) (.11) and (12) . The planes of these two modulations (11) andt ^" (12) are inclined to each other and their slopes are of different direction. The rotating shaft (2) has also two transverse holes (6) and (7) in the points, where it is equipped with the cam lobe angular movement system, which holes meet the longitudinal hole (8) and are also inclined in such a way as to coincide with the modulations (ramps) (11) and (12) of the transmission shaft (3) .

The move of the .shaft (3) on one direction forces,through the modulation (ramp) (11) , the ball (4) to slide inside the hole (6) and as it emerges, to push the cam lobe and rotate

arround its joint to the AB arc, which joint as mentioned be¬ fore is formed by modulations (9) and (10) .

During this gradual movement of the cam lobe its symmetry axis is shifted each time by a specific angle as to its initial position. The final position of its movement may in any case be defined, depending on the choise of rotation point location,the size of balls (.4) , (5) and the modulations (11) , (12) of the shaft (.3) .

In final position .the lobe is secured with the help of ball (5) and the recess (13) which is modulated in the inner surface of the one side of the cam lobe.

When the shaft (3) moves to the opposite to the former di¬ rection ceases to impose force on the ball (4) and pushes,through the modulation (ramp) (12) the ball (5) , which sliding inside the hole (7) enters the recess (13) of the lobe, forcing it to return gradually to an intermediate or final position. In this movement the lobe is helped by the force of the spring of the recpective valve which is pushing it.

During the angular gradual movement of' the symmetry axis of the cam lobe, which is achieved according to the above de¬ scribed rotation of the lobe arround a fixed point located off¬ set from its symmetry axis, the intended simultaneous gradual change of the valve lifting "x" (FIG.8) and the valve timing is achieved (phase change to a degree " " and (duration) opening -closing time of the valve, since everytime there is a change in the cam-respective lifter contact area) .

The cam lobe is designed in- such a way so that it coopera¬ tes completely with the cylindrical longitudinal shaft, at any position during its movement, with the purpose of achieving in any case a smooth contact with the respective lifter and avoiding anwanted noises.

Referring to FIG.9 we see a cam lobe angular movement sy¬ stem which consists of:

A specially shaped cam lobe (1) , a rotating longitudinal shaft (.2) ,a small cylindrical piston with sphericaly shaped end (.15) , a ball and return spring (16) .

The cam lobe (1) and the rotating shaft (2) have in this case too the modulations (9) and (10) for the creation of the

- 1 - joint as it was described in page 4.

The rotating shaft (2) ,at the points equipped with this system, has a transverse hole (17) , inclined to its perpendi¬ cular symmetry axis, and meeting the longitudinal hole (8) of the rotating shaft.

Through the longitudinal hole (8) hydraulic mean is de¬ livered under pressure' (e.g. oil) , which pushes the piston (15) which in turn sliding into the hole (17) enters through its sphericaly shaped end inside the spherical recess (18) , which is shaped on the one side of the cam lobe-. This movement ^' of the piston results in the angular movement of the lobe arround the joint and consequently in the lift and timing change of the respective valve.

By interrupting the pressure of-the hydraulic mean the lobe. returns to its initial position with the help of the ball and the return spring (16) and the specially designed recess (19) on the side of the lobe.

In this case too applies the description on page 5 concer¬ ning the special design of the cam lobe. Refering to FIG. 0-11 we see a cam lobe angular movement system which consits of:

The specially shaped .cam lobe (.1)., the rotating shaft (2) , the transmission shaft (3) , the .specially shaped pin (20) ,the specially threaded component (.21).. The specially shaped cam lobe has on one side, drilled to the whole thickness of the side, the- threaded hole (22) and on the other side, drilled to the whole thickness of the side, the hole (23) .

The rotating shaft (2) has in the points where it is equipped with the cam lobe angular movement system, two dia¬ metrically opposite holes, which holes meet the logitudinal hole of the shaft. One hole (24) has two opposite flat sides and two opposite semicylindrical sides, while hole (25) has a spherical shape. The pin (20) is shaped in such a way so that both the ends have a round cross section (cylindrical shape) , where as the middle part has a prismatic shape with two flat oppo¬ site sides and two semicylindrical opposite sides.

The specially threaded component (21) has a cylindrical shape one end shaped as a sphere corresponding to the sphe¬ rical shape of the hole (25) of the shaft (2) . The outer sur¬ face is threaded and fits with the threaded hole (22) of the cam lobe. The component has a hole drilled londitudinally through its whole length with a diameter corresponding to the one end of pin (20) . The slot on the flat side of the component is used for screwing and unscrewing the component. The longitudinal transmission shaft (3) , in addition to the longitudinal grooves on its outer surface (14) for the easing of lubricating mean circulation, has also at the coo¬ perating with the system points a hole (26) drilled through the whole diameter of the shaft, whose hole two opposite si¬ des are flat and parallel, while the two other sides have a semicylindrical shape. The flat sides of the hole are machi¬ ned inclined to the symmetry axis of the shaft.

The assebly of the whole system is carried out as follows: The longitudinal transmission shaft (3) through the longi- tundinal hole of shaft (2) and the specially shaped cam lobe (1) are assembled on ,the shaft (2) , so that the axis of the holes (22) , (23) , (24) , (25) and (26) coincide. Following that the pin (20) is assembled through all the above mentio¬ ned holes, so that the one cylindrical end of the pin is inser¬ ted inside the hole (23) , the prismatic shaped middle part is in the hole (26) and the other cylindrical end is in the hole (22) . In this hole is screwed the specially threaded component (21), in whose longitudinal hole penetrates the cylindrical end of the pin- (20) . In this way the whole system is secured. Additionaly the spherical end of the threaded component (21) and the respective spherical hole (25) of the shaft (2) form the joint arround which is able to rotate the cam lobe. Through the gradual proper screwing or unscrewing of the component (21) is- achieved the desired, each time, tolerance of the whole fit. The prismatic shaped middle part of the pin (20) and the hole (26) of the shaft (3) are machined so that they can ful¬ ly cooperate with each other.

This system functions as follows:

The longitudinal shaft (3) can move with the help of any suitable way or means along its axis towards the one or the other direction. This movement forces the pin (20) to slide on the inclined flat sides of the hole (26) and be raised or lowered in respect to its former position, depending on the direction of the shaft (3) movement.

This movement of pin (20) forces the cam lobe (-}) ,to ro¬ tate along the joint created as mentioned, between the compo¬ nent (21) and the hole (2.5) of shaft (2) . The slope of the flat sides of the hole (26) , its length as well as the- length of the hole (24) of shaft (2) properly selected define the maximum travel of pin (20) and consequently the final position of the rotational movement of cam lobe.

We point out there, that pin (20) is machined with a pri- smatic shaped-middle part, with two flat sides, so that during its cooperation with the respective sides of hole (26) , the wear rate of the material will be reduced, which wear rate would have been much greater, in the case of a cylindrical shaped pin and consequently its cooperation with the sides of the respective opening (26) would have- been along a line and not along a flat surface, as is the case now.

Concerning the rest,the cam lobe is in this case too, designed so that in any position during its movement will cooperate smoothly with the rotating shaft. In a variation--of this system the pin (20) has a special design,as seen in FIG.11, where the one end of the pin has the shape of the specially threaded component (21) and at the other the pin has a thread of the same form. The middle part is no longer of a prismatic shape but cylindrical. Also in this variation it is desired,the hole (23) of the cam lobe (1) to have a thread similar to the thread of pin (20) . Pin (20) passing through holes (23) , (24) , (25) and (26) is screwed with one end in the hole (23) and with the other end in the hole (22) . In this way the system is secured in a better way, especially in the cases where the center of rotation (joint) of the lobe,is required to be located somehow further apart from the rotating shaft (2) . In order to have a greater mating surface between the pin and the sides of hole (26) (as it was ,

in the case of the prismatic shape middle part pin (20)) , a tube-liner is machined- (27) with two flat parallel sides and longitudinal hole,inside which penetrates pin (20) ,so that, diaring the operation of the system to come in contact with the sides of the hole (26) the flat surfaces of tube-liner (27) and not the cylindrical pin.

In FIG.12 ( i) we see represented with a diagram the ope¬ rational characteristics of the valve when the cam lobe is in the initial position. In FIG.12 ( ι and (5) we see also in diagram form the operational characteristics of the valve in an intermediate and in the final position of the cam lobe respectively.

^" From the above mentioned diagrams is clear the picture of modification of the operational characteristics of the valve, during the movement of the cam lobe and consequently the improvement in the performance of the respective motor in the whole operational RPM range .