ITBO20120135A1 - BUTTERFLY VALVE WITH ANULAR DIFFUSION OF RECIRCULATING GAS FOR AN INTERNAL COMBUSTION ENGINE SUCTION DUCT - Google Patents

Description

DESCRIPTION

of the patent for industrial invention entitled:

â € œBUTTERFLY VALVE WITH RING DIFFUSION OF RECIRCULATING GAS FOR AN INTAKE DUCT OF AN INTERNAL COMBUSTION ENGINEâ €

TECHNIQUE SECTOR

The present invention relates to a throttle valve with annular diffusion of recirculation gas for an intake duct of an internal combustion engine. ANTERIOR ART

In modern internal combustion engines it is necessary to introduce recirculating gases into the intake circuit which may have different origins and must be mixed in the best possible way with the fresh air (i.e. the air coming from the external environment ) which is intended to be drawn into the combustion chambers of the cylinders to form the combustion agent.

The recirculation gases can include exhaust gases that are taken from the exhaust circuit by an EGR duct (â € œExhaust Gas Recirculationâ €) and have the function of improving the combustion process that takes place in the combustion chambers of the cylinders; the presence of an EGR duct is typical in a compression ignition engine of the mixture which operates according to the â € œDieselâ € cycle. Additionally, the recirculating gases may comprise fuel vapors which have been collected by a canister device. Finally, the recirculating gases may include vapors loaded with combustible products which have been collected by a bleeding device coupled to a lubricating oil sump.

European patent EP0768462B1 describes an annular flue gas recycling diffuser for an internal combustion engine equipped with an intake manifold regulated by a throttle valve. This diffuser comprises a support body which has a central air passage duct and is interposed between an outlet opening of the throttle valve and an inlet opening of the intake manifold; in the support body there is an annular distribution chamber that surrounds the air passage duct and externally presents a supply channel arranged tangentially through which it receives the gases to be recycled and internally presents an annular diffusion slot through which the gases to be recycled are introduced into the air passage duct.

However, the annular recycling diffuser described in the European patent EP0768462B1 has a non-negligible axial dimension which is added to the axial dimension of the throttle valve and which can therefore cause difficulties in placing inside a small engine compartment. Furthermore, the recycling ring diffuser described in the European patent EP0768462B1 is relatively expensive as it is made up of several pieces that must be assembled together.

DESCRIPTION OF THE INVENTION

The object of the present invention is to provide a throttle valve with annular diffusion of recirculation gas for an intake duct of an internal combustion engine, which throttle valve is free from the drawbacks described above and, at the same time, both of easy and cheap realization.

According to the present invention, a throttle valve with annular diffusion of recirculation gas is provided for an intake duct of an internal combustion engine, according to what is claimed by the attached claims.

BRIEF DESCRIPTION OF THE DRAWINGS

The present invention will now be described with reference to the attached drawings, which illustrate some non-limiting examples of embodiment, in which:

â € ¢ Figure 1 is a perspective view, in longitudinal section and with parts removed for clarity, of a butterfly valve with annular diffusion of recirculation gas made in accordance with the present invention;

â € ¢ Figure 2 is a partially exploded perspective view, in longitudinal section and with parts removed for clarity of the butterfly valve of Figure 1;

â € ¢ Figure 3 is a front view, in longitudinal section and with parts removed for clarity of the butterfly valve of Figure 1;

â € ¢ Figure 4 is a partially exploded perspective view with parts removed for clarity of the butterfly valve of Figure 1; And

â € ¢ Figure 5 is a front view, in longitudinal section and with parts removed for clarity of a variant of the butterfly valve of Figure 1. PREFERRED EMBODIMENTS OF THE INVENTION

In figures 1-4, the number 1 indicates as a whole a throttle valve 1 for an intake duct of an internal combustion engine. In particular, the butterfly valve 1 is directly coupled to an inlet port 2 of an intake manifold by means of the interposition of an annular sealing gasket 3.

The butterfly valve 1 allows the diffusion of recirculating gases in the fresh air (i.e. the air coming from the external environment) which is destined to be sucked into the combustion chambers of the cylinders to form the combustion agent. . The recirculation gases can include exhaust gases that are taken from the exhaust circuit by an EGR duct (â € œExhaust Gas Recirculationâ €) and have the function of improving the combustion process that takes place in the combustion chambers of the cylinders; the presence of an EGR duct is typical in a compression ignition engine of the mixture which operates according to the â € œDieselâ € cycle. Additionally, the recirculating gases may comprise fuel vapors which have been collected by a canister device. Finally, the recirculating gases may include vapors loaded with combustible products which have been collected by a bleeding device coupled to a lubricating oil sump.

The butterfly valve 1 comprises a tubular body 4 which has a symmetrical longitudinal axis 5; inside the tubular body 4 there is an air passage duct 6 through which the fresh air passes (i.e. the air coming from the external environment) which is fed to the intake manifold . A butterfly plate 7 is rotatably mounted inside the tubular body 4 to adjust the section of the air passage duct 6; in particular, the butterfly plate 7 is carried by a shaft 8 which is rotatably mounted in corresponding seats obtained through the tubular body 4 to rotate around a rotation axis perpendicular to the longitudinal axis 5 of the duct 6 for the passage of the € ™ air. One end (not shown) of the shaft 8 protrudes from the tubular body 4 to engage in an electric actuator device which controls the rotation of the shaft 8 (and therefore of the butterfly plate 7).

The butterfly valve 1 comprises an annular distribution chamber 9 which is arranged around the duct 6 for the passage of the air downstream of the butterfly plate 7 with respect to the direction of supply of the fresh air. The annular distribution chamber 9 internally has an annular diffusion slot 10 which puts the distribution chamber 9 in communication with the air passage duct 6. Furthermore, a feed hole 11 is provided which is arranged transversely to the longitudinal axis 5 of the air passage duct 6, passes through the tubular body 4, and flows into the distribution chamber 9 to feed the recirculation gas in the distribution chamber 9 itself. In the illustrated embodiment there is a single feed hole 11, but it is possible to have several feed holes 11 (for example a feed hole 11 connected to the EGR duct, a feed hole 11 connected to the canister, and a feed hole 11 connected to the lubrication oil casing); having more feeding holes 11 it is also possible to adapt the shape, dimensions and orientation of each hole to optimize the feeding of the corresponding type of recirculation gas (which have very different flow rates, densities, pressures and temperatures). Furthermore, the supply hole 11 can be arranged radially as illustrated in the attached figures, or it can be arranged tangentially (to favor a uniform diffusion of the recirculating gases throughout the annular distribution chamber 9).

In use, the recycling gases are fed with a certain pressure into the distribution chamber 9 through the supply hole 11 (or through the supply holes 11 if there are more supply holes 11) and then from the chamber 9 of distribution, the recycling gases enter, through the diffusion slot 10, into the passage duct 6 where they mix with the fresh air present in the passage duct 6 itself.

The tubular body 4 internally has an annular lip 12 which protrudes from an internal wall of the tubular body 4 and constitutes both an upper wall of the distribution chamber 9 and an upper edge of the diffusion slot 10. Furthermore, an annular grafted element 13 is provided, which is independent from the tubular body 4 (i.e. it is initially separated from the tubular body 4), it is coupled to the tubular body 4 to be arranged inside the duct 6 of passage of the air, and constitutes both a lower wall of the distribution chamber 9 and a lower edge of the diffusion slot 10. In other words, the distribution chamber 9 and the diffusion slot 10 are defined between the annular lip 12 of the tubular body 4 (which constitutes both an upper wall of the distribution chamber 9 and an upper edge of the diffusion slot 10) and the grafted element 13 (which constitutes both a lower wall of the distribution chamber 9 and a lower edge of the diffusion slot 10).

The distribution chamber 9 has an inverted `` U '' shape in longitudinal section (clearly visible in Figure 3), in which the upper cusp is constituted by the annular lip 12 which protrudes from an internal wall of the tubular body 4 and the lower base consists of an upper wall of the annular grafted element 13.

As previously said, the grafted element 13 is independent and initially separated from the tubular body 4 and is only inserted later in the tubular body 4. Preferably, the grafted element 13 is fixed by means of a mechanical interlocking inside the tubular body 4 (i.e. the grafted element 13 is forced into the tubular body 4) and the tubular body 4 has internally an annular tooth 14 against which an upper wall of the grafted element 13 rests. Normally, the inserted element 13 is made of plastic material by injection molding; on the other hand, the tubular body 4 can be made of metal or (more rarely) of injection-molded plastic material.

According to a preferred embodiment, the distribution chamber 9 has a progressively decreasing passage section towards the diffusion slot 10, in correspondence with which the minimum passage section is present; in this way, a `` Venturi effect '' occurs which determines a progressive increase in the speed of the recirculating gases as they approach the diffusion slot 10 and this increase in the speed of the recirculating gases favors a better mixing of the recirculating gases. recirculation in the fresh air present in the passage duct 6.

According to a preferred embodiment, the grafted element 13 has a thickness which is variable along the longitudinal axis 5 of the air passage duct 6 and is maximum immediately downstream of the diffusion slot 10; this shape of the inserted element 13 allows to improve the mixing of the recirculation gases in the fresh air present in the passage duct 6, as it determines an increase in section (and therefore a decrease in the forward speed of the fresh air ) of the passage duct 6 immediately downstream of the diffusion slot 10.

According to an alternative embodiment illustrated in Figure 5, the grafted element 13 comprises a plurality of fins 15 which protrude into the air duct 6 starting from an internal wall of the grafted element 13 same. Preferably, the fins 15 are helical-shaped to give a swirling trend to the fresh air present in the air passage duct 6 in order to improve the mixing of the recirculating gases in the fresh air present in the passage duct 6 .

The butterfly valve 1 described above has numerous advantages.

In the first place, the butterfly valve 1 described above is very compact, that is, it has a reduced axial dimension, making it easier to place it inside an engine compartment even of small dimensions; this result is obtained thanks to the fact that the distribution chamber 9 is made directly inside the tubular body 4 without entailing any elongation of the tubular body 4 with respect to the standard.

Furthermore, the butterfly valve 1 described above is simple and inexpensive to manufacture, as it allows the distribution chamber 9 and the corresponding diffusion slot 10 to be made by adding a single â € œnewâ € component (i.e. the element 13 inserted ) which is of inexpensive construction (it is, ultimately, a shaped plastic ring) and very fast assembly (it is sufficient to push with a certain force the element 13 inserted inside the tubular body 4) . It is important to note that even the tubular body 4 is devoid of "undercuts" and therefore can be easily made without any type of complication by means of a simple mold made up of only two parts that can be separated from each other. It is important to note that also the coupled element 13 illustrated in figure 5 is of inexpensive construction, since to make the fins 15 it is sufficient to use a mold equipped with a single unscrewing core.

The butterfly valve 1 described above has great flexibility in modifying the shape and / or dimensions of the distribution chamber 9 and of the corresponding diffusion slot 10: keeping the tubular body 4 (which is the most â € œcomplexâ €) unchanged. It is sufficient to vary the shape and / or dimensions of the grafted element 13 (which, as mentioned above, is ultimately a shaped plastic ring) to consequently vary the shape and / or dimensions of the distribution chamber 9 and of the corresponding diffusion slot 10.

Last but not least, the butterfly valve 1 described above allows an optimal mixing between the recycling gases and the fresh air present in the passage duct 6.

Claims (8)

R I V E N D I C A Z I O N I 1) Butterfly valve (1) with annular diffusion of recirculation gas for an intake duct of an internal combustion engine; the butterfly valve (1) includes: a tubular body (4) inside which there is a duct (6) for the passage of air; a butterfly plate (7) which is rotatably mounted inside the tubular body (4) to adjust the section of the air passage duct (6); an annular distribution chamber (9) which is arranged around the air passage duct (6) and downstream of the butterfly plate (7) and has an annular diffusion slot (10) which connects the distribution chamber (9) with the air passage duct (6); and at least one supply hole (11) which is arranged transversely to a longitudinal axis (5) of the air passage duct (6), passes through the tubular body (4), and flows into the chamber (9) distribution to feed the recirculation gases into the distribution chamber (9) itself; the butterfly valve (1) is characterized by the fact that it comprises an annular coupled element (13), which is independent from the tubular body (4), is coupled to the tubular body (4) to be arranged inside of the air passage duct (6), and constitutes both a lower wall of the distribution chamber (9) and a lower edge of the diffusion slot (10). 2) Butterfly valve (1) according to claim 1, wherein the tubular body (4) internally has an annular lip (12) which protrudes from an internal wall of the tubular body (4) and constitutes both an upper wall of the distribution chamber (9), and an upper edge of the diffusion slot (10). 3) Butterfly valve (1) according to claim 1 or 2, in which the inserted element (13) has a thickness which is variable along the longitudinal axis (5) of the duct (6) for the passage of the ™ air and is maximum immediately downstream of the diffusion slot (10). 4) Butterfly valve (1) according to claim 1, 2 or 3, in which the distribution chamber (9) has a progressively decreasing passage section towards the diffusion slot (10), in correspondence with which the minimum passage section. 5) Butterfly valve (1) according to one of claims 1 to 4, in which the coupled element (13) comprises a plurality of fins (15) projecting into the duct (6) for the passage of the Air starting from an internal wall of the grafted element (13) itself. 6) Butterfly valve (1) according to claim 5, in which the fins (15) are shaped like a helix to give a swirling trend to the air present in the air passage duct (6). 7) Butterfly valve (1) according to one of claims 1 to 6, wherein the tubular body (4) entirely has an annular tooth (14) against which an upper wall of the coupled element (13) rests. 8) Butterfly valve (1) according to one of claims 1 to 7, in which the engaged element (13) is fixed by means of a mechanical interlocking inside the tubular body (4).