The object of the present patent of invention is a new mechanical continuous transmission system which allows the conversion from a higher speed motor to a slower one by means of a drive shaft rotation speed.

Mechanisms to control drive shaft rotation speed are known in several different options and intended for several different functions. Usually known as "transmission" or "gearbox" due to its main function, that of shifting gears, by multiplying or dividing engine speed to the final drive, directly on the wheels or shaft with a power take-off so as to transform drive shaft power into power or speed, depending on the need. There are two main sequences of shafts in a typical gearbox: the primary shaft, which collects engine speed through the clutch, and the secondary shaft (output shaft) which transmits the rotation transformed into power or speed to the differential final shaft. Each shaft is provided with one or more gears with an equal or different diameter ratio so that, according to the meshing engagement, resulting speed is low, constant, or high in the output shaft. The greatest drawback of that model is the stepped shifting from one gear ratio to the other, which can cause discernible jerks while shifting. Continuously variable transmissions have been propelling motorcycles and low-displacement motorbikes for quite a long time in a construction having elastomeric and toothed pulleys and chains. An automotive manufacturer, though, has developed a transmission called Multitronic based on the principles of continuously variable transmission, but which comprises the transmission between two pulleys whose conical shape allows an almost infinite ratio variation. This type of transmission uses gears but shifting configuration is carried out as needed. It is more silent and sturdy thus enabling its use in more powerful engines; ratios can vary from 6 to 1 between the shortest and longest speed, something that regular transmissions cannot achieve.

There is also the double-clutch transmission or dual-clutch transmission (DCT) which uses two clutches and employs sophisticated electronics and hydraulics to control them just as they do in a standard automatic transmission. In a DCT, however, the clutches operate independently. One clutch controls the odd gears (first, third, fifth and reverse), while the other controls the even gears (second, fourth and sixth). Using this arrangement, gears can be changed without interrupting the power flow from the engine to the transmission. Notably, those are configurations denoting a great efficiency to continuously shift speed ratio although both have a very high cost.

Thus, in view of the problems evoked and with the purpose of solving them, the inventor has researched and developed the present model, titled CONTINUOUS TRANSMISSION SYSTEM, the main object of the present patent application comprising, in short, an input sliding gear with a shaft perpendicular to the shaft of a main disc, to which said input sliding gear is tangentially leaned to, being its diameter fixed and its relation with the main disc variable due to the diameter obtained by the point of the positioning thereof along the periphery of the main disc radius. The main disc contact point with the input sliding gear, whose rotation transmits less speed and more tractive force (torque), is the main disc higher diameter point. As the input sliding gear slides, bringing it closer to the main disc shaft, there is a progressive reduction of the diameter thereof at the contact point with the input sliding gear, thus changing speed and power ratio, reducing the tractive force and increasing the main disc speed. As noted, transition speed between speed and power is directly connected to the sliding speed of the input sliding gear in relation to the main disc, being that smooth and without any discernible jerks or changes. Speed variation is directly connected to the point in which the sliding gear contacts the main disc along its radius and correlated with its larger and smaller diameter. In the model presented, the main disc surface, as well as the sliding gear perimetral surface, are made up of anti- slipping material. Variants are also foreseen, always conforming to the same functional concept, wherein a first variant provides a secondary shaft and an output sliding gear which is pushed by the input sliding gear, thus providing multiplication in output speed of the main disc rotation.

Another great innovation in the object model of the present patent application the inventor has researched and developed, titled CONTINUOUS TRANSMISSION SYSTEM, is the possibility of having much larger ratios than conventional gear transmissions. Conventional gear transmissions have an average ratio of 1 :3 or 1:4, split into 5 speeds, whereas the continuous transmission, with a much simpler mechanism, can present a ratio several times larger. The CONTINUOUS TRANSMISSION SYSTEM can have a "simple" or a "square" ratio, which means that a same initial mechanism with an X ratio, when added a few parts, will possess a square X ratio. The simplified design prototype possesses a ratio of approximately 1:5, which can be raised to a ratio of 1:25 in its "square" variant. Notably, as can also be proved hereinafter, the CONTINUOUS TRANSMISSION SYSTEM denotes several innovations concerning the proposed functionality and mechanism, thereby being worth of the requested patent application.

The model, which is the object of the present patent application, can be better understood from the following description, including numerical references to the below- mentioned Figures without, however, limiting proportions and materials that may have to be employed on its industrial production, in which:

Figures 1 to 3 are, respectively, top frontal, top rear, and bottom frontal perspective views;

Figures 4 to 7 are, respectively, top, left side, frontal and rear views;

Figures 8 and 9 are right side views of the model, respectively, with the input sliding gear in two different angling degrees having an initial position in relation to the main disc; Figures 10 and 11 are right side views of the model, respectively, with the input sliding gear in two different angling degrees having a final position in relation to the main disc;

Figure 12 is a perspective view of the input sliding gear at its initial position in relation to the main disc;

Figure 13 is a perspective view of the input sliding gear at its final position in relation to the main disc, representing on the main disc surface its diameter ratio variations;

Figure 14 is a frontal perspective view of a variant of the model having the output sliding gear and showing the revolution directions thereof, the main disc and the input sliding gear. Sliding advance movement of input and output sliding gears is parallel;

Figure 15 is a top view of the variant of the model having the output sliding gear, the main disc and the input sliding gear. Sliding advance movement of input and output sliding gears is parallel;

Figure 16 is a right side view of the model in its variant having the output sliding gear illustrating the neutral angling moment of the input and output sliding gears and the initial position of both in relation to the main disc. Arrows indicate parallelism of input and output sliding gears, making evident the stability of the situation;

Figure 17 is a right side view of the model in its variant having the output sliding gear illustrating the advancement of the angling moment of the input sliding gear and the reverse angling of the output sliding gear at the initial position of both in relation to the main disc. Arrows indicate the direction of the movable components. Sliding advance movement of input and output sliding gears is parallel;

Figure 18 is a right side view of the model in its variant having the output sliding gear illustrating the advancement of the angling moment of the input sliding gear and the reverse angling of the output sliding gear and the final position of both in relation to the main disc. Arrows indicate the direction of movable components;

Figures 19 to 21 are top rear perspective views of the model in its variant having the output sliding gear illustrating the situations described in Figures 16 to 18. Sliding advance movement of input and output sliding gears is parallel; Figure 22 is a top rear perspective view of the model in another variant having the output sliding gear coupled to a rotating bearing shaft with respect to the main disc shaft, illustrating the initial position of the input and output sliding gears in relation to the main disc;

Figure 23 is a top rear perspective view of the model in its variant having the output sliding gear coupled a rotating bearing shaft with respect to the main disc shaft, illustrating the final position of the input and output sliding gears in relation to the main disc;

Figure 24 is a right side view of the model in its variant having the output sliding gear coupled to a rotating bearing shaft with respect to the main disc shaft, illustrating the final position of the input and output sliding gears in relation to the main disc and the possibility of rotation of the output shaft in relation to the main disc shaft;

Figures 25 and 26 are cross-sectional details of the switch, in both perspective and side views, showing the guide cutout conicity. These Figures represent the component found in the two input sliding assemblies, primary (6) and secondary (7), and in the two output sliding assemblies, primary (9) and secondary (10);

Figures 27 and 28 are cross-sectional details of the track and switches, in both perspective and side views, showing the guide cutout conicity and its position on the track;

Figures 29 and 30 are cross-sectional details of the sliding gear flexible articulated assembly showing its position with variable angling in relation to the shaft (Figure 30) controlled by the switch (4). These Figures represent the components found in the two input sliding assemblies, primary (6) and secondary (7), and in the two output sliding assemblies, primary (9) and secondary (10);

Figure 31 is an enlargement of detail A of Figure 6;

Figure 32 is an enlargement of detail B of

Figure 22.

According to the above-mentioned

Figures and as many as necessary to illustrate the present patent application, the CONTINUOUS TRANSMISSION SYSTEM comprises a frame (1) provided with tracks (2) and a control carriage (3) having a control lever (3a) supported on a bearing (3b) and spacers (3c and 3d) connecting the control carriage (3) to the switches (4 and 5) on their spin shaft (4a and 5a), colinear to the guide cutout shaft (4b and 5b) describing (Figures 25 to 28) a conicity which allows a limited angular movement between the switches (4 and 5) and the track (2) obtained by the control lever (3a) motion, by means of control arms (3e) coupled to switch bearings (4c and 5c), and perpendicular to the spacers (3c and 3d);

Two distinct moments are described in the principle of operation of the CONTINUOUS TRANSMISSION SYSTEM, being MP -

Maximum Power moment and MS - Maximum Speed moment.

The control lever (3a) presents three different stages: I-

Neutral = control lever (3a) is in the central position (Figure 9) and maintains gear ratio stable where it currently is; II- Speed = Pushing control lever (3a) forward (Figure 10), transmission starts upshifting, in a continuous and progressive way, while control lever (3a) is in said position; III- Power =

Pulling control lever (3a) backwards (Figure 11) starts downshifting and consequent power increase; two input sliding assemblies, primary (6) and secondary (7), are provided with a primary (6a) and a secondary (7a) input sliding gear, each coupled to a primary (6b) and secondary (7b) driven ring, and to the switches (4 and 5), said driven ring (6b and 7b) being away from the drive shaft (primary-6e or secondary-7e), but the same driven ring (6b and 7b) is connected to the drive ring (6c and 7c) by means of a flexible link (6d and 7d) which allows the sliding gears (6a and 7a) to tilt at an angle by means of the flexible link (6d and 7d) twisting, thus maintaining traction in relation to the main disc (8), provided by the drive ring (6c and 7c) and its connection to the drive shaft (primary-6e or secondary-7e) which is driven by an electric motor, by combustion, by pedals or others, coupled to one of the drive shafts (primary-6e or secondary-7e) or to both of them. The drive shafts (primary-6e or secondary-7e) can have a hexagonal or splined configuration or even other profiles allowing the longitudinal sliding of the assemblies (Figure 29).

Thus, for instance, if the input sliding gears (6a and 7a) have an "X" diameter and the main disc (8) a maximum contact diameter of "5X" and a minimum contact diameter of "IX", equal to the "X" diameter of the input sliding gears (6a and 7a), the result is a variable ratio of 1:5 to 1: 1. The main disc (8) can be configured by 5 connected discs (Figure 31), being one of them central (8a) and made of steel, two made of nylon (8b) to increase thickness, and two outer ones made of anti-slipping material (8c), fixed to one other and coupled to the main shaft (8d) journaled in main bearings (8e) which also serves as a support for the drive shafts (primary-6e or secondary-7e). Said main shaft (8d) allows power transfer and power output from the main disc (8) and can be connected to any device an individual wishes to drive or to a power take-off through the main shaft (8d) driven by an electric motor, by combustion, by pedals or others, and having coupled to the main disc (8) one or more output sliding assemblies that can operate independently or in a synchronized way.

It should be pointed out the several possibilities of composition and formation of the main disc and other transmission components with the use of several different ultra light and/or super-resistant materials, "composites", and etc, according to the foreseen use.

Control lever position (3a) forward forces the switch bearings (4c and 5c), by means of control arms (3e) and the switches (4 and 5), to rotate (Figure 10) on their spin shaft (4a and 5a), thus allowing the input sliding gears (6a and 7a) to tilt forward and, thus, advance, while rotating, towards the center of the main disc (8).

A primary drive gear (6f) drives the primary drive shaft (6) and, in reverse rotation, a secondary drive gear (7f) drives the secondary drive shaft (7). That assembly provides a combined drive of the main disc (8) two faces.

A variant (Figures 14 to 21) provided with two output sliding assemblies, primary (9) and secondary (10), each configured as the two input sliding assemblies, primary (6) and secondary (7), with primary (9a) and secondary (10a) output sliding gears, each coupled to a primary (9b) and secondary (10b) driven ring, and to the switches (11 and 12), said driven ring (9b and 10b) being away from the drive shaft (primary-9 and secondary-lOe), but the driven ring (9b and 10b) being connected to the drive ring (9c and 10c) by means of a flexible link (9d and 1Od) which allows the output sliding gear (9a and 10a) to tilt at an angle by means of the flexible link (9d and 1Od) twisting, thus maintaining traction in relation to the main disc (8). In this variant (Figures 14 to 21), sliding advance movement of the two input sliding assemblies, primary (6) and secondary (7), and of the two output sliding assemblies, primary (9) and secondary (10), is parallel and synchronized by the auxiliary spacers (13 and 14) fixed in top points in the switches (4 and 5) and bottom points in the switches (11 and 12). The main disc (8), driven by the input sliding assemblies, primary (6) and secondary (7), drives the two output sliding assemblies, primary (9) and secondary (10), in reverse rotation and, simultaneously, the primary (9f) and secondary (1Of) auxiliary drive gears. One end of the drive shafts (primary-9 and secondary-lOe) is fixed to the main bearings (8e) and at its opposite end pulleys, several gears or a propeller shaft and a differential can be coupled, thus obtaining a gear ratio at the output assembly whose result will be the input assembly square ratio. The drive shafts (primary-9e and secondary-10e) can be used in conjunction with the main shaft (8d), thus allowing independent drives with different speeds for different attachments.

Another variant (Figures 22 to 24) is provided with at least one articulated output sliding assembly (15) configured by a sliding switch (15a) on an auxiliary track (15b), an articulated drive shaft (15c) and a shaft guide (15d) mounted on the end of the auxiliary track (15b). An auxiliary gear (15e) is coupled to the switch (15a) and is also coupled to the articulated drive shaft (15c), which in turn, is supported and fastened to the auxiliary main bearing (8f) provided with a gear (8g) which is linked with two ring gears (18) which, arranged on the same side of the gear (8g), provide a combined motion of the output sliding assemblies, primary (9) and secondary (10), and the articulated output sliding assembly (15), thus obtaining a gear ratio whose result will be the input assembly square ratio. The auxiliary track articulated setting (15b) on the auxiliary main bearing (8f) allows the output assembly (Figure 24) to rotate around the main shaft (8d), thus enabling an adaptation of the drive shaft (primary-9e and secondary-lOe) angular positioning. The main disc (8), driven by the input sliding assemblies, primary (6) and secondary (7), drives the auxiliary gear (15e) and its articulated drive shaft (15c) wherein it can be coupled to any attachment, directly or by means of an additional pulley or gear, and which can be used in conjunction with the main shaft (8d), thereby allowing independent drives with different speeds for different attachments or the same speeds for differently positioned attachments.

Notably, the model introduced and explained in details above in its manual version, can also be automated, including electronic management of manner of use and components power (engine, transmission and attachments or traction), by connecting pneumatic, hydraulic or electrical mechanisms for sliding the control carriage (3), the two input and output sliding assemblies, primary (9) and secondary (10), switch linkage (4 and 5 and 11 and 12), as well as the articulated output sliding assembly linkage (15), in its described variant (Figures 22 to 24). Suppression of one of the two input sliding assemblies, primary (6) and secondary (7), may also be provided.