ES1266236U - Valve for a combustion engine, valve system and combustion engine comprising said valve system (Machine-translation by Google Translate, not legally binding) - Google Patents

Abstract

Valve for a combustion engine, characterized in that it comprises: - a rotary axis (1) configured to rotate about a longitudinal axis, - a plate (2) attached to the rotary shaft (1) and secured to it (1), the plate (2) being configured so that the rotation of the rotary shaft (1) produces the rotation of the plate (2) around the longitudinal axis, the plate (2) comprising a guide element (3) arranged on an outer surface of the plate (2), where the guide element (3) defines a closed perimeter around the longitudinal axis and where the distance of the guide element (3) is variable with respect to the longitudinal axis of the rotary axis (1) along said closed perimeter, - a lever (4) comprising: - a fixed first end (4.1), the lever (4) being configured to rotate around said first end (4.1), the axis of rotation being parallel to the longitudinal axis of the rotary axis (1), - a second extreme (4.2), - a guided element (4.3) located between the first end (4.1) and the second end (4.2) and arranged in connection with the guide element (3) of the plate (2) so that the guided element (4.3) is movable along the closed perimeter defined by said guide element (3), - a closing element (5) with an arcuate shape attached to the second end (4.2) of the lever (4), where the closing element (5) is movable between a closing position, where the closing element (5) plugs an opening of a combustion chamber and an opening position, where the closing element (5) releases said opening, where the guide element (3), the guided element (4.3), the lever (4) and the closing element (5) are configured so that the guide element (3) induces a rocking movement of the closing element (5) with respect to the first end (4.1) of the lever (4) between the closed position and the open position of the valve. (Machine-translation by Google Translate, not legally binding)

Description

DESCRIPTION

Valve for a combustion engine, valve system and combustion engine comprising said valve system

Field of the invention

The object of the present invention is a valve for a combustion engine. Another object of the invention is a valve system comprising a set of valves according to the invention and a combustion engine comprising said valve system.

State of the art

Poppet valves are known in the state of the art. These valves are used in combustion engines to open and close the intake and exhaust of the engine cylinders.

The poppet valve comprises a closing element, for example a flat metal disc. Said closure element is attached to a stem that has its longitudinal axis perpendicular to the disk that makes up the closure element. The stem pushes the metal disc in a longitudinal motion along the longitudinal axis and opens the valve. The closure element rests on a seat ring, normally circular in section. As the closure element approaches the seat, the passage section is reduced and therefore the pressure drop increases by decreasing the flow rate.

Poppet valves also have a spring that is generally used to close the valve when the stem is not actuated.

The combustion engine normally operates the valves by acting on the stems through cams and tappets. The profile and position of the cams determine the moment and speed of the valve opening.

Summary of the invention

The valve object of the invention comprises:

• A rotary axis configured and arranged to rotate about a longitudinal axis.

• A plate attached to the rotating shaft and integral with it. In this way the plate is configured so that the rotation of the rotary axis causes the rotation of the plate about the longitudinal axis of the rotary axis. The plate is a sheet of metal, or other material, rigid and not very thick. The plate comprises a guide element arranged on an outer surface thereof. The guide element defines a closed perimeter around the longitudinal axis and furthermore the distance of the guide element is variable with respect to the longitudinal axis of the rotary axis along said closed perimeter.

• A lever comprising:

^or a first end that is fixed. The lever is configured to rotate around said first end. The axis of rotation of the first end is parallel to the longitudinal axis of the rotary axis,

^or a second extreme,

^or a guided element located between the first end and the second end and located in connection with the guide element of the plate so that the guided element is movable along the closed perimeter defined by said guide element.

• A valve closure element. The closure element has an arcuate shape and is attached to the second end of the lever. The closure element it is movable between a closing position, where the closing element plugs an opening in a combustion chamber and an opening position, where the closing element releases said opening.

In this way the guide element, the guided element, the lever and the closing element are configured such that the guide element induces a rocking movement of the closing element with respect to the first end of the lever between the closed position and the position valve opening. Therefore, the closing element performs a reciprocating movement between both the closing and opening positions of the valve to plug, that is, to close the opening of the combustion chamber.

The valve is based, therefore, on the rotary movement of an axis, the longitudinal axis, with a plate that rotates around said longitudinal axis, which guides the lever that will perform an alternative movement between two positions so that the element closing describes an arc. The arc-shaped closing element will be the mechanism for opening and closing the combustion chamber of the cylinder, allowing the blocking of gases to said combustion chamber, or the entry or exit of said gases, depending on whether the valve is a valve. inlet or a combustion chamber exhaust valve, respectively.

The first end of the lever has a single degree of freedom, allowing rotation around it. Said rotation occurs on an axis that is parallel to the rotary axis. The lever, therefore, has a rocking movement, that is, a reciprocating movement between the two closed and open positions of the valve.

The opposite end of the lever is attached to the closure element which has an arcuate shape. In an exemplary embodiment, said closure element can be an arched plate. The closing element is moved by the movement of the lever from the closed position of the combustion chamber of the cylinder to the open position of said combustion chamber.

Said reciprocating movement occurs due to the displacement of the guided element along the guide element. The rotation of the plate around the longitudinal axis of the rotary axis and the geometry of the guide element force the movement of the guided element.

Another object of the present invention is a valve system comprising a set of valves according to the aforementioned characteristics and an engine comprising said valve system.

The valve system object of the invention comprises the set of plates of the set of valves attached to a single rotary axis that induces the rotation of the set of plates around the longitudinal axis of the rotary axis. According to one embodiment, the plates are located equidistant along the longitudinal axis of the rotary axis, all the plates being equally oriented with respect to the longitudinal axis, so that the rocking movement of each of the plates that make up the system is parallel to each other.

The valve object of the invention has numerous advantages with respect to the seat valves normally used in combustion engines and with respect to other types of valves:

- Increases the efficiency of the engine since the resistance to the opening of the valves due to the springs disappears.

- It facilitates the precise control of the air / mixture inlet to the combustion chamber by modifying the guide element.

- It occupies less space in the motor since the opening and closing is produced by a tilting movement of the closing element instead of by a linear movement along the longitudinal axis of the stem. This results in a thinner cylinder head which also reduces the weight and the engine's center of gravity. Being a system implanted on the lateral of the cylinder head there is also a decrease in the center of inertia of the engine in the vertical axis.

- Reduction in the size of the reduction gear as there is a variation in the synchronism with respect to the crankshaft. In an exemplary embodiment, for every 720 degrees of rotation of the crankshaft, the plates of the present valve rotate 360 degrees around the longitudinal axis of rotation.

- In the open position, the area available for the air / mixture inlet or outlet is greater than in poppet valves. In addition, the closing element does not interrupt the entry path of the mixture, which allows a fluid entry into the combustion chamber, increasing the volumetric efficiency of the cycle.

- Simple design and small dimensions. It involves few moving elements and few elements between which friction occurs.

- The design allows a state-of-the-art spring seat valve head to be used as a base.

- It allows to adapt to the synchronism of the engine by means of a usual timing belt.

Taking into account the above advantages, the valve object of the invention solves the technical problem of improving the operation of valves in combustion engines.

Description of the figures

To complete the description and in order to provide a better understanding of the invention, figures are provided. Said figures form an integral part of the description and illustrate an embodiment of the invention.

Figure 1 shows a front, plan and side view of an embodiment of the valve object of the invention.

Figure 2 shows a front view of the valve corresponding to the embodiment of Figure 1 in a closed position.

Figure 3 shows a front view of the valve corresponding to the embodiment of Figure 1 in an open position.

Figure 4 shows a plan view of an exemplary embodiment of a valve system of a combustion engine with four valves intended to be placed on four cylinders. The position of each plate and its corresponding closing element is also shown according to the embodiment of figure 1 for each of the four valves.

Detailed description of the invention

Figure 1 shows a front, plan and side view of an embodiment of the valve object of the invention. The valve represented comprises:

• The rotary axis (1) that rotates around its longitudinal axis. . This rotary axis (1) has been represented as a hollow cylinder, and it can be a solid cylinder along its entire length.

• The plate (2) attached to the rotating shaft (1) and secured to it (1). In the exemplary embodiment shown, the plate (2) corresponds to a disk. The rotation of the rotary axis (1) produces the rotation of the plate (2), or disk, around the longitudinal axis of the rotary axis (1). The plate (2) or disk is arranged such that its geometric center coincides with the longitudinal axis of rotation.

• A guide element (3) is located on an outer surface of the plate (2), said outer surface being substantially perpendicular to the longitudinal axis. In the embodiment shown, the disk comprises a first and a second face perpendicular to said longitudinal axis, and the guide element (3) is specifically located on one of said first or second faces.

As can be seen in the front view of figure 1, the guide element (3) comprises along its length a variable distance with respect to the longitudinal axis of the rotary axis (1). The guide element (3) is a cavity made in said first or second face of the plate (2), being able to be a partial hole or a through hole in said plate (2). A guided element (4.3) in the form of a lug and arranged in said guide (3) will generate a reciprocating movement of a closing element (5) of the valve, as will be explained later.

• A lever (4), comprising:

^o A first end (4.1) that is fixed and around which the lever (4) can rotate along an axis parallel to the longitudinal axis of the rotary axis (1).

^o A second end (4.2), opposite to the first end (4.1) of the lever (4), which is attached to the closing element (5).

^o The guided element (4.3) located between the first end (4.1) and the second end (4.2). In the exemplary embodiment shown, the guided element (4.3) corresponds to a pin that is in connection with the guide element (3) of the plate (2) so that the pin moves along said guide element ( 3).

• The closing element (5) with an arcuate shape which corresponds in the exemplary embodiment to an arcuate plate.

In this way, the guide element (3), the guided element (4.3), the lever (4) and the closing element (5) are configured so that the guide element (3) induces the reciprocating movement of the closing element. (5) with respect to the first end (4.1) of the lever (4) between a closed position and an open position of the valve.

In the exemplary embodiment shown, the guide element (3) is a cavity arranged in one of the outer surfaces of the plate (4) and the guided element (4.3) is a lug that is inserted into the cavity of the guide element (3 ). The figure has schematically represented said lug and said cavity. It is understood that, in order to optimize the displacement of said pin along the cavity, it can be of circular geometry or even include bearings, thus reducing the friction coefficients and minimizing the possibilities of interlocking of the pin with respect to the cavity, especially in the areas of change of geometry of said cavity. Likewise, the teat may comprise a "T" shaped profile, which is inserted into a cavity in a complementary way to said "T" shaped profile. The objective is to prevent the pin from dislodging from the cavity during its movement through the cavity.

Alternatively, in another embodiment, the guide element (3) can be a projection of the plate (4) and the guided element (4.3) embrace the guide element (3). Likewise, it is understood that, in order to optimize the displacement, the guided element (4.3) can be of a "U" -shaped geometry that embraces a projection in a complementary way. Said alternative can include bearings, thus reducing the coefficients of friction and minimizing the possibilities of interlocking of the pin with respect to the cavity, especially in the areas of change of geometry of the guide element (3).

Figure 2 shows a front view of the disc or plate (2), the lever (4) and the closing element (5) in a closed position. The guide element (3) changes its inclination, causing the pin to force the valve to close. In this figure, the guided element (4.3) has entered the area of the guide element (3) that is at a greater distance from the longitudinal axis of the rotary axis (1). While the guided element (4.3) is arranged in this section of the guide element (3), the lever (4) is kept at one end of its reciprocating or reciprocating movement around the first end (4.1), keeping the closing element ( 5) in its closed position of the combustion chamber of the respective cylinder.

In figure 3 these elements are shown in an open position of the valve. The lug follows the cavity marked on the disc. By changing the shape of the cavity, the pin forces the lever (4) to move and thus the valve opens. Thus, in this figure, the guided element (4.3) is arranged at the point of the guide element (3) that is the smallest distance from the longitudinal axis of the rotary axis (1). While the Guided element (4.3) is arranged at this point of the guide element (3), the lever (4) is arranged at the opposite end of its reciprocating or reciprocating movement around the first end (4.1), keeping the closing element (5 ) in its open position in the combustion chamber of the respective cylinder.

In the exemplary embodiment shown, the cavity defining the guide element (3) does not pass through the plate (2), although in another exemplary embodiment, the cavity could pass through the plate (2).

In an exemplary embodiment, in order to improve the sliding between the guided element (4.3) and the guide element (3) and as mentioned above, either the guided element (4.3) itself, or the element guide (3), may include bearings on their surface that would interpose between both elements (3, 4.3).

In the shown embodiments, the guide element (3) is symmetrical with respect to an axis of symmetry of the plate (2). In this way it is achieved that the rocking movement between the opening and closing of the valve is carried out in a uniform way. More specifically, the axis of symmetry is included in the outer surface of the plate (2) and passes through the longitudinal axis.

In the embodiment shown, the guide element (3) comprises a circular section and a V-shaped section. Along the circular section the distance to the longitudinal axis is constant, and corresponds to the section of the guide element (3) that it is arranged at a greater distance from the longitudinal axis. The central part of the V is at a smaller distance from the longitudinal axis of the rotary axis (1) than the two ends of the V, said ends being in turn connected to the circular section. The inclination of the V section will define the closing and opening speed of the closing element (5).

The V-shaped geometry forces the lever (4) to abandon its vertical position, when the arcuate plate of the closing element (5) closes the combustion chamber of the cylinder, and induces a rotational movement to said lever (4) , forcing the arcuate plate to move into its open position.

In an exemplary embodiment, the guide element (3) may comprise roundings in the connection areas between the circular section and the V-shaped section, and also a rounding in the central area of said "V" section. In this way, the displacement of the guided element (4.3) in the guide element (3) is improved, avoiding efforts between the two that could damage the system.

In the embodiment shown, the closing element (5) is concave with respect to the axis of rotation of the first end (4.1) of the lever (4), in such a way that the closing element (5) accompanies the rocking movement with its shape.

Also in the exemplary embodiment shown, the closing element (5) is connected by one of the ends of the arch to the lever (4). Other options would be possible, for example, that the lever (4) was attached to the center of the arc of the closing element (5).

Figure 4 shows an example of an embodiment of the valve system of a four-cylinder engine. The system comprises a set of valves as described above. For this, it comprises a rotary axis (1) that rotates around its longitudinal axis and that is common to the set of plates (2). The plates (2) are located equidistant along the rotary axis (1).

The valve system drives the intake valve assembly or the exhaust valve assembly. For the other set of valves, another system is necessary that generates the movement of the valves, and it may be the system presented in the present invention or a different one.

In the embodiment example of figure 4, in addition, each plate (4) comprises a guide element (3) with the same morphology, but rotated with respect to the longitudinal axis of the rotary axis (1) by the same number of degrees with respect to the guide element ( 3) of the contiguous plates (4). More specifically, in the example shown, the guide element (3) of each plate (4) is rotated 90 ° with respect to the guide element (3) of the adjacent plate (s) (4).

As shown in said figure 4, the closing element (5) of the first valve is arranged in its combustion chamber opening position, as its respective guided element (4.3) is at the midpoint of the section in V of the guide element (3). For their part, the closing elements (5) of the second, third and fourth valves are arranged in their closed position of the combustion chamber, as their respective guided element (4.3) is at different points of the circular section of the guide element. (3). Thus, it is observed that the circular section of the guide element (3) extends substantially three-quarters of its perimeter extension. For its part, the "V" section of the guide element (3) extends substantially a quarter of its perimeter extension.

In an exemplary embodiment, the rotary shaft rotates like a camshaft, 360 degrees for every 720 degrees of the crankshaft.

Finally, an internal combustion engine comprising at least one valve system as described above is also an object of the invention. Said system can be located in the intake, in the exhaust or in both.

Claims (13)

1 Valve for a combustion engine, characterized in that it comprises: • a rotary axis (1) configured to rotate around a longitudinal axis, • a plate (2) attached to the rotary axis (1) and secured to it (1), the plate (2) being configured so that the rotation of the rotary axis (1) produces the rotation of the plate (2) around the longitudinal axis, the plate (2) comprising a guide element (3) arranged on an outer surface of the plate (2), where the guide element (3) defines a closed perimeter around the longitudinal axis and where the distance of the guide element (3) is variable with respect to the longitudinal axis of the rotary axis (1) along said closed perimeter, • a lever (4) comprising: ^or a fixed first end (4.1), the lever (4) being configured to rotate around said first end (4.1), the axis of rotation being parallel to the longitudinal axis of the rotary axis (1), ^or a second extreme (4.2), ^or a guided element (4.3) located between the first end (4.1) and the second end (4.2) and arranged in connection with the guide element (3) of the plate (2) so that the guided element (4.3) is movable along the closed perimeter defined by said guide element (3), • a closing element (5) with an arcuate shape attached to the second end (4.2) of the lever (4), where the closing element (5) is movable between a closing position, where the closing element (5) stops an opening of a combustion chamber and an opening position, where the closing element (5) releases said opening, where the guide element (3), the guided element (4.3), the lever (4) and the closing element (5) are configured so that the guide element (3) induces a rocking movement of the closing element (5 ) with respect to the first end (4.1) of the lever (4) between the closed position and the open position of the valve. 2. - Valve for a combustion engine according to claim 1, characterized in that the plate (4) is a disk. 3. - Valve for a combustion engine, according to any one of the preceding claims, characterized in that the guide element (3) is symmetrical with respect to an axis of symmetry of the plate (2), where the axis of symmetry is comprised in the outer surface of the plate (2) and passes through the longitudinal axis. 4. - Valve for a combustion engine according to claim 3, characterized in that the guide element (3) is a projection of the plate (4) and the guided element (4.3) hugs the guide element (3). 5. - Valve for a combustion engine, according to claim 3, characterized in that the guide element (3) is a cavity on the outer surface of the plate (4) and the guided element (4.3) is a lug configured for its introduction into the cavity of the guide element (3). 6. - Valve for a combustion engine, according to any one of claims 3 to 5, characterized in that the guide element (3) comprises a circular section, where the distance to the longitudinal axis is constant along said circular section, and a V-shaped section, where the central part of the V is at a smaller distance from the longitudinal axis of the rotary axis (1) than the two ends of the V and where said two ends are connected with the circular section. 7. - Valve for a combustion engine according to any one of the preceding claims, characterized in that the closing element (5) is concave with respect to the axis of rotation of the first end (4.1) of the lever (4). 8. - Valve for a combustion engine according to any one of the preceding claims, characterized in that the closing element (5) is attached to one end of the arc to the lever (4). 9. - Valve system, characterized in that it comprises a set of valves according to any one of the preceding claims and that the set of plates (2) of the set of valves are integral with a single rotating shaft (1) configured to induce the rotation of the set of plates (2) around the longitudinal axis of the rotary axis (1). 10. - Valve system according to claim 9, characterized in that the plates (2) of the set of plates (2) are located equidistant along the longitudinal axis of the rotary axis (1). 11. - Valve system according to any one of claims 9 or 10, characterized in that each plate (4) comprises a guide element (3) with the same morphology, where each guide element (3) of each plate (4) it is rotated with respect to the longitudinal axis of the rotary axis (1) by the same number of degrees with respect to the guide element (3) of the adjacent plate (s) (4). 12. - Valve system according to claim 11, characterized in that it comprises four valves where each guide element (3) of each plate (4) is rotated with respect to the longitudinal axis of the rotary axis (1) 90 ° with respect to the guide element ( 3) of the contiguous plate / s (4). 13. - Internal combustion engine, characterized in that it comprises at least one valve system according to any one of claims 9 to 12.