ITTO20120127A1 - NEW PRESSURE ROTARY MECHANICAL DEVICE. - Google Patents

Description

Description of the Industrial Invention entitled:

â € œMechanical rotating pressure deviceâ €

DESCRIPTION

The present invention refers to a rotating mechanical pressure device.

No mechanical rotary pressure devices of this type are currently known.

The object of the present invention is to provide a rotating mechanical pressure device which allows to produce the power required for various applications, without propellant, increased or reduced as desired. Some preferable applications of the inventive device are any plant in the industrial, domestic (for example a power generator) or transport field.

The above and other objects and advantages of the invention, as will emerge from the following description, are achieved with a rotary mechanical pressure device as described in claim 1. Preferred embodiments and non-trivial variants of the present invention form the subject matter of dependent claims.

The present invention will be better described by some preferred embodiments, provided by way of non-limiting example, with reference to the attached drawings, in which:

- Figure 1 is a side view of a preferred embodiment of the device of the invention;

- Figure 2 is a front view of the device of the invention seen from the side of the arrow A in Figure 1;

- Figure 3 is a partial view of the device of Figure 2 which illustrates the detail of the toothed wheels;

- Figure 4 is a front view of the device of the invention seen from the side of the arrow B in Figure 1;

- Figure 5 is a sectional view of the device of Figure 3 seen along the section line C-C;

- Figure 6 is a sectional view of the device of Figure 3 seen along the section line D-D;

- Figure 7 is a sectional view of the device of Figure 3 seen along the section line D-D;

Figure 8 is a sectional view of the device of Figure 5 seen along the section line F-F, which better illustrates the axle 05 of the inventive device;

Figure 9 is a sectional view of the device of Figure 5 seen along the section line G-G, which better illustrates the axle 04 of the inventive device;

Figure 10 is a sectional view of the device of Figure 5 seen along the section line H-H, which better illustrates the axle 03 of the inventive device;

- Figure 11 is a sectional view of the device of Figure 6 seen along the section line I-I, which better illustrates the axle 01 of the inventive device;

Figure 12 is a sectional view of the device of Figure 6 seen along the section line L-L, which better illustrates the axle 06 of the inventive device;

- Figure 13 is a sectional view of the device of Figure 6 seen along the section line L-L1;

- Figure 14 is a sectional view of the device of Figure 6 seen along the section line M-M, which better illustrates the axle 02 of the inventive device;

Figure 15 is a sectional view of the device of Figure 6 seen along the section line N-N, which better illustrates the axle 07 of the inventive device;

- Figure 16 is a sectional view of the device of Figure 7 seen along the section line O-O, which better illustrates the axle 08 of the inventive device;

Figure 17 is a sectional view of the device of Figure 7 seen along the section line P-P, which better illustrates the output axle 10 of the inventive device;

Figure 18 is a sectional view of the device of Figure 7 seen along the section line Q-Q, which better illustrates the axle 09 of the inventive device; And

- Figure 19 is a top view of the inventive device from the side of the arrow R in Figure 1, which represents the overall dimensions of the gear wheels, supports and structure.

With reference to the Figures, a preferred embodiment of the rotary pressure mechanical device according to the present invention is illustrated and described. It will be immediately obvious that innumerable variations and modifications (for example relating to shape, dimensions, arrangements and parts with equivalent functionality) can be made to what has been described without departing from the scope of the invention as appears from the attached claims.

With reference to the Figures, the mechanical rotary pressure device of the present invention is an autonomous and self-sufficient technical device which, through a series of toothed wheels and other components, produces a rotary movement, applying physical and mechanical laws.

The gears with involute teeth, on the circumference of the wheels, to prevent stalling, are flanked on both sides by smooth flanged discs with a slightly larger radius.

The movement input is given by the push on the upper lever 1 which, by pivoting on the fulcrum Î ±, acts on the middle lever 2 which, pivoting in turn on the fulcrum β, acts on the lower lever 3, which, by pivot on fulcrum Ï ‡, acts on the shaped module made up of parts 9 and 10.

The pressure, increased from lever to lever and articulated by the pin Î ́, passes to the internal pressure module 11.

The function of compensating and blocking the considerable thrust imparted to the shaped module 9, 10 with another useful and opposite thrust, belongs to the upper pressure module 7 which, being connected with the shaped module 9, 10, intermediate to the head module (upper pressure module) and to the terminal (internal pressure module 11), is articulated by the pin ε.

The pressure accumulated in the internal pressure module 11 is discharged directly onto four coaxial bearings 01 / N, covered by a reinforcement ring 16: two on the double toothed shaft (made up of parts 12, 13, 14, 15, 16, 17) and identified as axle 01 (Figure 11), and two on the twin toothed shaft identified as axle 02 (Figure 14).

These shafts are flanked and parallel to the line of the first level (section C-C of Figure 3) with the flanged gear wheels à ̃p.100 (à ̃p = pitch diameter), and consequently side by side and parallel to the line of the second level (section D-D of Figure 3) with the gear wheels à ̃p.24.

The reinforced bearings, pressed in this way, start the simultaneous rotation of the double-toothed shafts (axle 01/02). The starting is transmitted from the flanged gear wheel à ̃p.100 (axle 02) to the flanged gear wheel à ̃p.72 (consisting of parts 22, 23), identified as axle 03 (Figure 10), always placed on the first level.

Axle 03 pushes and directs the flanged gear wheel à p.100 (axle 02) towards the flanged and sprung gear wheel à p.72 (made up of parts 22, 23, 24, 25), identified as axle 04 (Figure 9).

In fact, two spiral springs 02 / N are applied to the axle 04, interfaced and held in place by two screws with ground shank 03 / N: this application maintains consistency between the axles 01 and 02. The axle 04 reverses the its direction of rotation, with respect to the axle 01 and to the axle 02, maintaining its position and facilitating starting.

The movement, in synchronized progression, passes from the flanged gear wheel à p.50 (made up of parts 18, 19, 20) identified as axle 05 (Figure 8), and simultaneously from the axle 03 placed on the first level, to the two gear wheels à ̃p.72 fixed on support 26 and identified as axle 06 (Figure 12) and axle 07 (Figure 15), both placed on the second level.

From these the motion is passed to the two double toothed shafts (composed of parts 29, 30, 31) identified as axle 08 (Figure 16) and axle 09 (Figure 18), fixed on the support 33.

These axles have a gear wheel à p.100 placed on the second level and a gear wheel à p.24 placed on the third level (section E-E of Figure 3): these latter wheels mesh together with the gear wheel à ̃p.110 32 identified as output axle (Figure 17) placed on the third level.

The fine-tuning of the screw inserts 6 and the stabilizers, made up of M16 type 04 / N screws coupled with concave and convex 05 / N washers, prepares the start-up phase.

The drive shaft must be connected to the output axle 10, because, at the peak of its rotating force, the system achieves maximum power through two speed reductions.

The sequence of levers interconnected by the three pressure modules and the other components, suitably assembled and related to the size, pitch diameter (Ã ̃p) and number of wheels, allows to produce the necessary power, without propellant, increased or reduced ad libitum .

This product of the pressure exerted by the various components is applicable to any plant in the industrial, domestic (for example a power generator) or transport sector, and uses clean energy, in line and harmony with the nature ecosystem.

The mechanical device is mounted on a structure 35, 36, and lubricated with oil.

The essential characteristics of the inventive device are the following:

1) the bearings are coaxial to all the gear wheels. The device is started by subjecting to pressure a couple of bearings for the axle 01 and a couple for the axle 02, by means of a series of levers synchronized with other modules. Before this stage, the screw inserts and all other adjustment elements must be fine-tuned. This is essential for keeping the overall rotating attitude constant and adjustable. The power produced, without propellant, directly proportional to the radius of the wheels (low on the axle 01 and on the axle 02, high on the output axle 10) makes it broadly applicable to any plant for industrial or domestic use. or transport, using clean energy.

2) In order for the motion of the gears to be reliable, continuous and free from vibrations and seizure risks, each toothed wheel placed at the first level (axles 01, 02, 03, 04 and 05) is flanked on both sides by smooth flanged discs , with a radius slightly greater than the pitch diameter (Ã ̃p). This is the main feature of the device, and it will be the reference point for other future projects. The mechanical assembly is mounted on a metal structure and is lubricated with oil.

Claims (9)

CLAIMS 1. Mechanical rotary pressure device adapted to produce power for industrial, domestic or transport plants, said device comprising: - a plurality of toothed wheels (axle 01, axle 02, axle 03, axle 04, axle 05) operatively connected to an internal pressure module (11); - a plurality of levers (1, 2, 3) adapted to actuate the toothed wheels (axle 01, axle 02, axle 03, axle 04, axle 05) by acting on the internal pressure module (11); characterized by the fact that each toothed wheel (axle 01, axle 02, axle 03, axle 04, axle 05) is flanked on both sides by smooth flanged discs, with a radius slightly greater than the pitch diameter (à ̃p) of the toothed wheels (axle 01, axle 02, axle 03, axle 04, axle 05). 2. Rotary mechanical pressure device according to claim 1, characterized in that a thrust on an upper lever (1) of said plurality of levers (1, 2, 3), by means of a pin on the fulcrum Î ±, acts on a lever median (2) which, by pivoting in turn on a fulcrum β, acts on a lower lever (3), which, by pivoting on a fulcrum Ï ‡, acts on a shaped module (9, 10) operationally connected to the module of internal pressure (11) transmitting to them the pressure, increased from lever to lever and articulated by a pin (Î ́) of the shaped module (9, 10). 3. Rotary mechanical pressure device according to claim 2, characterized in that the function of compensating and blocking the pressure imparted to the shaped module (9, 10) with another useful and opposite thrust, belongs to a higher pressure module (7) which, being connected with the shaped module (9, 10), intermediate to the upper pressure module (7) and to the internal pressure module (11), is articulated by a pin (ε). 4. Rotary mechanical pressure device according to claim 2 or 3, characterized in that the pressure accumulated in the internal pressure module (11) discharges directly onto coaxial bearings (01 / N), covered with a reinforcement ring (16) , two of said coaxial bearings (01 / N) being placed on a first double toothed shaft (axle 01, 12, 13, 14, 15, 16, 17), and two of said coaxial bearings (01 / N) being placed on a second shaft with twin double toothing (axle 02). 5. Mechanical rotary pressure device according to claim 4, characterized by the fact that said bearings (01 / N) are adapted to initiate the simultaneous rotation of the first and second double toothed shaft (axle 01, axle 02), the starting by transmitting from the second flanged toothed wheel (axle 02) to a third flanged toothed wheel (axle 03, 22, 23), said third flanged toothed wheel (axle 03) being able to push and direct the second flanged toothed wheel (axle 02) towards a fourth flanged and sprung toothed wheel (axle 04, 22, 23, 24, 25). 6. Rotary mechanical pressure device according to claim 5, characterized in that two spiral springs (02 / N) are applied to the fourth toothed wheel (axle 04), interfaced and held in place by two screws with ground shank ( 03 / N), in order to maintain consistency between the first and second toothed wheel (axle 01, axle 02), called fourth toothed wheel (axle 04) by reversing its direction of rotation, with respect to the first toothed wheel (axle 01 ) and to the second toothed wheel (axle 02), maintaining its position and facilitating its starting. 7. Rotary mechanical pressure device according to claim 6, characterized in that the movement, in synchronized progression, passes through a fifth flanged toothed wheel (axle 05, 18, 19, 20), and at the same time by the third toothed wheel (axle 03), to a sixth toothed wheel (axle 06) and a seventh toothed wheel (axle 07) fixed on a support (26). 8. Rotary mechanical pressure device according to claim 7, characterized in that, from the sixth and seventh toothed wheel (axle 06, axle 07), the motion is passed to an eighth shaft with double toothing (axle 08, 29, 30, 31) and a ninth shaft with double toothing (axle 09), fixed on a support (33), called eighth and ninth shaft with double toothing (axle 08, axle 09) having two toothed wheels placed on different levels and able to mesh together with an output gear wheel (10) connected to a transmission shaft. Mechanical rotary pressure device according to any one of the preceding claims, characterized in that it is mounted on a structure (35, 36) and lubricated with oil.