ITUB20155273A1 - TRANSFORMATION DEVICE FOR AN ALTERNATIVE MOTION IN A CONTINUOUS ROTARY MOTION - Google Patents

Description

Description of the patent for industrial invention entitled: "DEVICE FOR TRANSFORMING AN ALTERNATIVE MOTION INTO A CONTINUOUS ROTARY MOTION"

DESCRIPTION

Scope of the Invention

The present invention relates to a device for transforming a reciprocating motion into a continuous rotary motion, in order to produce electrical energy.

Brief introduction to the prior art

Devices for transforming an alternative motion into a continuous motion are known. An example is described in document GE2014A000101 in the name of the same Applicant.

In light of this solution, the need is felt to: constructively simplify the transformation device according to the prior art, thereby increasing its possible applications in other fields of the art, and improve performance and reliability.

Summary of the Invention

It is therefore an object of the present invention to provide a device for transforming a reciprocating motion into a continuous rotary motion which improves the performance and efficiency of the systems according to the known art.

It is another object of the present invention to provide a device for transforming a reciprocating motion into a continuous rotary motion which is constructively simple and economical to produce.

These and other purposes are achieved by a device for transforming a reciprocating motion into a continuous rotary motion which comprises:

- a first transmission unit adapted to move with reciprocating translational motion in a first translation direction and in a second translation direction opposite to said first translation direction;

- a second transmission unit adapted to receive the translational motion from said first transmission unit and transform it into rotary motion;

- means for generating electrical energy functionally connected to said second transmission unit and adapted to receive said rotary motion to transform it into electrical energy,

wherein said first transmission assembly comprises a rack element and said second transmission assembly comprises a flywheel functionally connected to a first freewheel element and to a second freewheel element functionally connected to said rack element,

wherein said first freewheel element has a first torque direction and said second freewheel element has a second torque direction opposite to said first torque direction,

in such a way that when said rack element moves in said first translation direction said first freewheel element moves in said first torque direction and results in a driving configuration for the transmission of motion, while said second freewheel element is in an insane configuration,

and such that when said rack element moves in said second translation direction, said second freewheel element moves in said second torque direction and results in a driving configuration for the transmission of motion, while said first freewheel element is in idle configuration, in such a way that a continuous rotary motion is transmitted to said flywheel.

Advantageously, said first and second freewheel elements are coupled to a main transmission shaft of said flywheel, said main transmission shaft being equipped with a motion transmission member, in particular a toothed wheel.

In particular, each of said first and second freewheel elements comprises respectively:

- a secondary shaft,

- a motion transmission gear mounted at a first end of said secondary shaft functionally coupled to said rack or pinion element;

a motion transmission gear mounted at a second end of said secondary shaft, opposite said first end, functionally coupled to said motion transmission member.

Preferably, said first and second freewheel elements are mounted facing each other in such a way as to embrace the rack and the toothed wheel on opposite sides.

In particular, said rack element comprises a first and a second face opposite each other which are respectively coupled with the respective transmission gear of the first and second freewheel elements.

In particular, the connection of the transmission gear and the return gear respectively with the rack and with the toothed wheel of the first and second freewheel element, is fixed. The first and second freewheel elements have opposite torque directions, i.e. an opposite direction of motion transmission such that in the transverse movement of the rack in the first direction of translation, only the first freewheel element is active. while the second remains insane. Vice versa, in the transversal movement of the rack in the second direction of translation, opposite to the first, the second freewheel element is active - that is, it transmits a driving force - while the first remains idle. In this way it is still possible to obtain a continuous rotation of the flywheel. In other words, the reciprocating motion of the rack is transformed into a continuous motion of the flywheel in an efficient and effective way. In a preferred embodiment, said device for transforming a reciprocating motion into a continuous rotary motion is integrated in a plant for the exploitation of wave motion energy, said plant comprising: at least a hollow column in which a float is housed; at least one water inlet opening in said column, positioned in such a way that water fluctuations due to wave motion determine a bidirectional lifting or lowering translation of said float along said column;

wherein said float is integrally connected to said rack element.

In particular, said flywheel is coupled to a generator to which it transmits a continuous rotation motion, in particular with a single direction of rotation. Advantageously, the use of the flywheel allows to ensure continuity in the rotation of the main shaft of the means of generating electricity.

Brief description of the drawings

Further characteristics and / or advantages of the present invention will become clearer with the following description of several embodiments, given by way of non-limiting example, with reference to the attached drawings in which:

Figure 1 shows a perspective view of a device for transforming a reciprocating motion into a continuous rotary motion according to the present invention;

Figure 2 shows a perspective view of the transformation device of Figure 1 applied to a plant for exploiting the wave motion;

Figure 3 shows a schematic view of the operation of the exploitation plant of Figure 2.

Description of preferred embodiments

With reference to Figure 1, a device 1 for transforming a reciprocating motion into a continuous rotary motion is shown which comprises a first transmission unit 2 configured to move with an alternating translational motion generated for example by a wave motion or other source, in a first translation direction d1 and in a second translation direction d2 opposite to the first translation direction d1.

A second transmission group 3 is also provided, structured to receive the translational motion from the first transmission group 2 and transform it into rotary motion. The second translation group 3 is in turn associated with means for generating electrical energy 5 or generator functionally connected to the second transmission group 3 which convert the rotary motion into electrical energy, according to known principles.

In particular, the first transmission group 2 comprises a rack element 4, while the second transmission group 3 comprises a flywheel 6. The flywheel 6 is functionally connected to a first freewheel element 7 and to a second freewheel element 8 functionally connected to the rack element 4.

According to the operating principle, each of the freewheel elements has a torque direction in which it is capable of transmitting a driving torque, while in a second opposite direction of rotation it rotates freely in neutral, not opposing resistance.

In the configuration of the device according to the present invention, the first freewheel element 7 has a first torque direction d and the second freewheel element 8 has a second torque direction c2 opposite to the first torque direction c1. In this way, when the rack element moves in the first translation direction d1, the first freewheel element 7 moves in the first torque direction d and results in a driving configuration for the transmission of motion, while the second freewheel element 8 results in neutral configuration. Vice versa, when the rack element 4 moves in the second translation direction d2 the second freewheel element 8 moves in the second torque direction c2 and results in a driving configuration for the transmission of motion, while the first freewheel element 7 it results in an idle configuration, so that a continuous rotary motion is transmitted to the flywheel 6.

More specifically, the first and second freewheel elements 8 are coupled to a main transmission shaft 9 of the flywheel 6. The main transmission shaft 9 is equipped with a motion transmission member, in particular a toothed wheel 10.

Instead, each freewheel element 7,8 comprises respectively a secondary shaft 7a, 8a, a transmission gear 7b, 8b of the motion mounted at a first end of the secondary shaft 7a, 8a functionally coupled to the rack element 4 or rack , and a transmission gear 7c, 8c mounted at a second end of the secondary shaft 7a, 8a, opposite the first end, functionally coupled to the toothed wheel 10. Structurally, the freewheel elements 7,8 are mounted facing each other. with respect to each other in such a way as to embrace the rack 4 on opposite sides, with the transmission gears 7b, 8b and the toothed wheel 10 with the transmission gears 7c, 8c. To achieve this configuration, the rack element 4 advantageously comprises a first and a second face opposite each other which are respectively coupled with the respective transmission gear 7b, 8b of the first and second freewheel element 7/8.

The connection of the transmission gear 7b, 8b and of the transmission gear 7c, 8c with the rack 4 and with the toothed wheel 10 is fixed. The first and second freewheel elements 7,8 have opposite torque directions, i.e. an opposite direction of motion transmission such that in the transverse movement of the rack in the first translation direction d1 is active - i.e. transmits a driving force - only the first freewheel element 7 while the second 8 remains idle. Vice versa, in the transversal movement of the rack in the second direction of translation d2, opposite to the first, the second freewheel element 8 is active - that is, it transmits a driving force - while the first 7 remains idle. In this way it is still possible to obtain a continuous rotation of the flywheel 6. In other words, the reciprocating motion of the rack is transformed into a continuous motion of the flywheel 6 in an efficient and effective way.

In a possible technical application shown in Figures 2 and 3, the transformation device I described above is integrated in a plant 20 for the exploitation of wave energy. The plant 20 comprises a hollow column 21 in which a float 22 is housed The column has at least one water inlet opening 23 into the column. The opening is obtained in the column in such a way that the fluctuations of the water with respect to a level L due to the wave motion determine a bidirectional lifting or lowering of the float 22 along the column 21.

The float 22 is integrally connected to the rack element 4.

In this way the vertical displacement of the float produces an alternating movement of the rack which therefore moves in a translational motion. According to the operating principle described above, the translational motion is transformed into continuous rotary motion on the flywheel 6 and converted into electrical energy by means of the generator.

The above description of more specific embodiments is able to show the invention from the conceptual point of view so that others, using the known art, will be able to modify and / or adapt such specific embodiments in various applications without further research and without departing from the inventive concept, and, therefore, it is understood that such adaptations and modifications will be considered as technical equivalents. The means and materials for carrying out the various functions may be of various kinds without thereby departing from the scope of the invention. It is understood that the expressions or terminology used have a purely descriptive purpose and therefore not limitative.

Claims (8)

CLAIMS 1. A device (1) for transforming a reciprocating motion into a continuous rotary motion comprising: - a first transmission unit (2) adapted to move with reciprocating translational motion in a first translation direction (d1) and in a second translation direction (d2) opposite to said first translation direction (d1); - a second transmission unit (3) adapted to receive the translational motion from said first transmission unit and transform it into rotary motion; - electrical power generation means (5) functionally connected to said second transmission group (3) and adapted to receive said rotary motion to transform it into electrical energy, wherein said first transmission group (2) comprises a rack element (4) and said second transmission group (3) comprises a flywheel (6) connected to a first freewheel element (7) and to a second element with free wheel (8) functionally connected to said rack element, wherein said first freewheel element (7) has a first torque direction (d) and said second freewheel element (8) has a second torque direction (c2) opposite to said first torque direction c (1) , in such a way that when said rack element moves in said first translation direction (d1) said first freewheel element (7) moves in said first torque direction (d) and results in a driving configuration for the transmission of the motion, while said second freewheel element (8) is in an idle configuration, and such that when said rack element moves in said second translation direction (d2) said second freewheel element (8) moves in said second torque direction (c2) and results in a driving configuration for the transmission of motion, while said first freewheel element (7) is in an idle configuration, so that a continuous rotary motion is transmitted to said flywheel (6). Transformation device (1) according to claim 1, wherein said first (7) and second (8) freewheel element are coupled to a main transmission shaft (9) of said flywheel (6), said drive shaft main transmission (9) being equipped with a motion transmission member (10). Transformation device (1) according to claim 2, wherein said motion transmission member is a toothed wheel (10). Transformation device (1) according to any one of claims 1-2, wherein each of said first (7) and second (8) freewheel element comprises respectively: - a secondary shaft (7a, 8a), - a motion transmission gear (7b, 8b) mounted at a first end of said secondary shaft (7a, 8a) functionally coupled to said rack element (4); - a transmission gear (7c, 8c) of the motion mounted at a second end of said secondary shaft (7a, 8a), opposite to said first end, functionally coupled to said motion transmission member (10). 5. Transformation device (1) according to any one of claims -3-4, wherein said first (7) and second (8) freewheel element are mounted facing each other in such a way as to embrace opposite parts of said rack element (4) and said toothed wheel (10). Transformation device (1) according to any one of claims -4-5, wherein said rack element (4) comprises a first and a second face opposite each other which are respectively coupled with the respective transmission gear (7b, 8b) of the first (7) and second (8) freewheel element. Transformation device (1) according to any one of claims -1-6, wherein said flywheel (6) is coupled to a generator to which it transmits a continuous rotation motion, in particular with a single direction of rotation. 8. Plant (20) for exploiting energy from wave motion comprising said device for transforming (1) a reciprocating motion into a continuous rotary motion, said plant (20) comprising: - at least one hollow column (21) in which a float is housed (22); - at least one water inlet opening (23) in said column (21), positioned in such a way that the fluctuations of the water due to the wave motion determine a bidirectional translation of raising or lowering of said float (22) along said column; wherein said float (22) is integrally connected to said rack element (4).