This invention is related to a coiled spring system utilizing at a maximum level, the pressure created within the cylinder that extends the momentum arm on the crank, for external and internal combustion engines with pistons including those with spark-plug ignition.

Problem to be solved by the Invention

The invention is related to the internal and external combustion engines with pistons including those with sparkplug ignition.

Today, the diameter of rotation of the crank axle journal is equal to the piston course in all traditional engines . There is no other system which has a larger rotation diameter of the crank axle journal while the piston course remains constant.

In every traditional engine, the piston, connecting-rod and the crank are mounted directly to each other and the rotation diameter of crank axle journal is equal to the piston course. In the system of our invention, there exists a system consisting of a pair of cams operating with

coiled spring, between the connecting rod and the crank axle journal or pully block, as shown in Figure 3 and 4. In this system the connecting rod tries to rotate the crank axle journal with more pressure. Besides, since the gyration radius of the crank axle journal or pulley block will increase the momentum arm also increases and therefore a greater torque and power is provided with a higher rotating power and longer momentum arm.

Detailed Explanation of the Drawings

Figure 1 shows at a 180° rotation circle of an engine according to the invention the crank axle journal angle is assumed to be 0°, while both internal and external eccentric cams are at the upper dead point the positions of coiled spring arms of internal and external cams at connecting rod and piston 45°-90°-135° and 180° are shown separately.

In Figure 1 the parts are shown with the following numerals:

Part No. Item

1 Piston

2 Cylinder

3 Connecting rod

4 Internal eccentric (cam)

5 Spring coiling (loading) arm

6 External eccentric (cam)

7 Spring hangers

8 Oil gaps

L Acquired useful diameter increase

Figure 2 shows the position of the internal and external eccentrics of piston at 0° - 90° and 180 ° angles (when the piston is on the upper dead position the accepted angle is 0°, the position of the spring and also the displacement of the center of connecting rod rotating the crank axle journal. This provides a supplement like "L" for the rotation diameter of the crank axle journal at 180° position.

In this figure numeral 9 is the joining spring.

Figure 3 is the diagram which shows the crank shaft, connecting rod, internal and external eccentrics, joining arms (spring arms) loads of joining arms and joining springs are on the upper dead position and the spring is at the joining position.

Figure 4 is the diagram which explains the transformation of energy consumed for winding the spring into a useful form.

Detailed Description of the Invention

The spring system which may be hydraulic, mechanical or electrical) taking advantage of the fuel exploding within the cylinder which extends the momentum arm, in the internal and external combustion engines with piston, operates as being assembled on the crank, connecting rod or piston. Figures 2 and 3 show the inner structure of the crank shaft connecting rod on the crank.

In the internal and external combustion engines with piston including those with spark-plug ignition, the said spring system takes advantage at a maximum level of the pressure provided in the cylinder which extends the momentum arm and with this characteristic of the spring system, a greater

rotation radius is obtained that of the crank journal in another engine on the same course. Thus, the momentum arm is also increased , the two eccentric parts on the crank shaft are seen in Figure 3; over these parts the connecting rod is placed. The parts (5) supported by the bearings (7) load the spring within the eccentric while the piston ascends towards the dead point; as the piston reaches this point the spring is completely loaded.

Position No. 1 in Figure 2: while the piston descends towards lower dead point, the springs starts to unwind and the eccentrics within the connecting rod rotate in opposite directions and push the connecting rod upward, while the pressure of the exploded gas in the cylinder pushes it down, and these two forces combine in order to rotate the crank.

Position No. 3 in Figure 2 when the piston is at lower dead point, the spring will be completely unwound and the eccentric will hold the connecting rod at a raised position with "L" distance.

While a typical engine course is expected to be equal to the rotation diameter, this engine according to the invention increases the rotation diameter with an amount of "Ii" at the same course.

This difference of diameter ("L" distance) advantageously increases the rotation diameter of the crank axle journal of the crank and thus the crank axle journal is produced so as to rotate with a larger diameter. Since the momentum arm rotating the crank gets bigger, a rotation momentum greater than that of a traditional engine of a similar course is applied.

In addition, as the piston of the present invention remains at an upper position in the cylinder with respect to a

traditional engine, the pressure coming over the piston is higher and thus the force rotating the crank shaft is larger. A bigger rotation momentum is obtained as the pressure and momentum arms are also increased.

While completing the cycle of the crank, the spring within the eccentrics mounted on the crank shaft is coiled by means of spring hangers. The force spent to wind the spring is recovered in order to rotate the crank. One of the most important advantages of this system is the increasing of the rotation diameter of the crank axle journal without changing the cylinder course; thus extending the momentum arm and having a high pressure since the piston remains at an upper position and thus by means of high pressure and a big momentum arm, increasing the torque and force.

It is also possible to transfer the energy consumed to wind the spring into a useful form so that the cylinder may be designed to provide high air charge in order to pump the air into it.

Thus the compression ratio may be modified in such a manner that the pressure within the cylinder shall be high enough after explosion.

This spring system may also be applied outside the crank as well as inside it. For instance, connected rod may be constructed of two parts fitting into each other and a spring coiled while fitting these two parts. The windings and unwinding of the spring is controlled by supplementary means, i.e. desired rotation is provided by directing guides. For instance, buffers may be placed on the connecting rod, spring hangers etc. to prevent the piston from hitting towards the dead point. Further, the same advantageous system may be provided by hydraulic, mechanical and electro magnetic systems and the rotation

diameter of crank journal may be increased while the piston course (stroke) remains constant or changes insignificantly. This provides with great advantageous besides the torque and force increase. However, one of the most important issues is the fact that a suitable spring selection is performed by calculating the force of the spring between interior and exterior eccentrics with respect to the construction and position of the location where this force is applied. Thus selection of the spring is made depending on the construction. The spring may be in such forms as helical, spiral or leaf spring.

Energy ' consumed to wind the spring may be transformed into a useful form as seen in Figure 4, applying the system shown in the same figure.

In the momentum diagram in Figure 4;

a- momentum arm under the effect of the spring b- Momentum arm activating the compressor piston b+c spring winding arm (hanger) pm - vertical force applied on hanger bearing pk - force providing the compression of air setting the winding spring while the piston moves toward the upper dead point (force received from crank pulley) py - force generated under the effect of winding springs.

Starting from the arrangement of this system:

py (a + b + c) - pk (b + c) + ph(c) = pm

Starting from the "0" equation,

py (a + b + c) + ph (c) = pk (b + c) .

Then, by changing ph, pm becomes "0". Thus the pressure on the spring winding hanger is brought almost to zero. With

the force to come on the "H" point, air is pumped with an air cylinder into the engine cylinder or into the tank. This air is sent out of the engine cylinder so that more air is charged into the cylinder. This helps the engine power, cycle, efficiency and torque. Air may also be used for different purposes.

This arrangement may be made for the small eccentric part as well as for the big one. Therefore, the force spent to wind the spring is recovered in the form of air from both sides .

This invention may be applied to all internal and external combustion engines with pistons (including those with spark-plug ignition) . However, this implementation should be made during the production stage of the engines.