FR3046633A1 - INTERNAL COMBUSTION ENGINE COMPRISING AN EXHAUST GAS RECYCLING SYSTEM - Google Patents

Abstract

Internal combustion engine (2) comprising: - an engine block (3) comprising at least one cylinder (4); - a cylinder head (5) provided with at least one intake duct (10) and an exhaust duct (11), and defining with the cylinder a combustion chamber (6); - an intake manifold (7) comprising at least one intake pipe (13) connected to a plenum (12); an exhaust manifold (8) connected to the exhaust duct; an exhaust gas recycling system (9) connected to the intake manifold and the intake duct, the system comprising a heat exchanger (23).

Description

INTERNAL COMBUSTION ENGINE COMPRISING AN EXHAUST GAS RECYCLING SYSTEM

The invention relates to the field of motor vehicles. It relates, more specifically, the recycling of the exhaust gas of an internal combustion engine mounted on a motor vehicle.

[0002] An internal combustion engine generally comprises an intake manifold, in which a gas is circulated to a combustion chamber of the engine.

The engine also comprises an exhaust manifold, in which the exhaust gases from the combustion chamber.

[0004] The combustion of the fuel generates harmless substances, such as water vapor, carbon dioxide or nitrogen, but also harmful emissions, such as carbon monoxide (CO), nitrogen oxides (NOx ) and hydrocarbon particles (HC).

[0005] These toxic substances represent only a small part of the total emissions of a modern engine. Most of the exhaust consists of nitrogen, water and carbon dioxide.

It is essential that this small amount of toxic substances be neutralized.

To reduce the formation of nitrogen oxides (NOx), the engines can be equipped with an exhaust gas recirculation circuit. This device is managed by the engine control computer, in a closed loop on a flowmeter setpoint.

The exhaust gas pulsed into the exhaust manifold are transferred to the intake circuit, through a valve. The valve is actuated by a solenoid valve, controlled proportionally by the engine control computer. The engine control computer measures the amount of fresh air admitted, thanks to the flowmeter, and determines the rate of exhaust gas recirculation.

[0009] The advantage of exhaust gas recirculation systems is that they reduce nitrogen oxide (NOx) emissions, meet European pollution standards, slow down the rate of combustion, and reduce the rate of combustion. proportion of oxygen in the gas, to reduce the thermal capacity of the gases, and therefore reduce their temperature during combustion.

However, the exhaust gas recycling systems are bulky, and must be inserted into a limited space of the engine enclosure.

US 4615324 discloses an internal combustion engine comprising a combustion chamber fed with gas by an intake duct, the engine comprising an exhaust gas recirculation circuit, provided with a communication hole disposed under the intake duct, so as to discharge the exhaust gas from the combustion chamber, by means of a communication pipe.

However, the exhaust gas recirculation circuit is not without drawbacks. Indeed, this circuit is subjected to thermal stresses, since the exhaust gases are at high temperature and that these exhaust gases are reintroduced into the combustion chamber, which results in a loss of power of the combustion engine. internal.

A first objective is to provide an exhaust gas recirculation system of a compact internal combustion engine, and can easily integrate into the engine enclosure, without having to reduce certain components of the engine.

A second objective is to provide a system for recycling the exhaust gas of an internal combustion engine, for cooling the exhaust gas before reintroducing it into the combustion chamber.

For this purpose, it is proposed, in the first place, an internal combustion engine comprising: an engine block comprising at least one cylinder; a cylinder head, provided with at least one intake duct and an exhaust duct, and defining with the cylinder a combustion chamber an intake manifold, comprising at least one intake pipe connected to a plenum; an exhaust manifold connected to the exhaust duct; an exhaust gas recirculation system connected to the intake manifold and the intake duct, the system comprising a heat exchanger.

Advantageously, such a system allows to reroute a portion of the exhaust gas emanating from a combustion chamber, for reinjecting into the combustion chamber through an intake duct.

This system makes it possible to cool the exhaust gases before reintroducing them into an intake duct.

Various additional features may be provided, alone or in combination: the system comprises at least one section integral with the heat exchanger and connected, on the one hand, to the intake duct and, on the other hand, the intake pipe; the system comprises a connection support, integral with the heat exchanger; the system comprises a valve, connected to the connection support, and adapted to manage the flow of the exhaust gases in the heat exchanger; the breech is hollowed out by a channel of diversion; the exhaust manifold comprises a primary deflection pipe, opening into the deflection channel; the system comprises a secondary deflection pipe, connected to the deflection channel and the connecting support; the connection support integrates an air filter; the connecting support is hollowed out with a passage for introducing the exhaust gases into the heat exchanger; the system comprises a flow channel, dug in the heat exchanger, extended by at least one flow pipe opening into the profile.

It is proposed, secondly, a motor vehicle comprising an internal combustion engine.

Other features and advantages of the invention will appear more clearly and concretely on reading the following description of embodiments, which is made with reference to the accompanying drawings, in which: FIG. a perspective view of a motor vehicle (in dotted lines) comprising an internal combustion engine (in continuous bold lines), FIG. 2 is an exploded perspective view, from above, of the engine of FIG. 1, equipped with 3 is a perspective view, seen from above, of the engine of FIG. 1, equipped with the exhaust gas recycling system. FIG. 4 is a sectional view along the section plane IV-IV of the engine of FIG. 3, equipped with the exhaust gas recirculation system, FIG. 5 is a sectional view along the sectional plane; VV, the engine of Figure 3, equipped with the exhaust gas recirculation system, Figure 6 is a perspective view, seen from above, of the exhaust gas recirculation system.

In Figure 1 is shown a vehicle 1 automobile (in dashed lines) comprising an internal combustion engine 2 (in bold continuous lines).

One defines with respect to the vehicle 1 an orthogonal reference XYZ comprising three axes perpendicular two by two, namely: - an axis X, defining a longitudinal direction, horizontal, coincides with the general direction of movement of the vehicle, - an axis Y, defining a transverse direction, horizontal, which with the X axis defines a horizontal XY plane, - a Z axis, defining a vertical direction, perpendicular to the horizontal XY plane.

In the remainder of the description and with reference to the reference defined above, the terms "longitudinal" or "longitudinally" refer to a direction coincident with the X axis, the terms "transverse" or "transversely >> refer to a direction confused with the Y axis, and the terms "vertical" or "vertically" refer to a direction coincident with the Z axis.

As illustrated in Figure 2, the internal combustion engine 2 comprises a motor block 3, dug at least one cylinder 4 and on which is deposited a cylinder head 5.

The cylinder 4 and the cylinder head 5 together form a combustion chamber 6.

The engine 2 comprises an intake manifold 7, for injecting a gas into the combustion chamber 6, and an exhaust manifold 8 for exhausting the exhaust gas from the combustion chamber 6.

The intake manifold 7 is advantageously made of a synthetic material (polymer, composite) in order to reduce its mass. In variants, the intake manifold 7 is metallic (for example cast steel or aluminum).

An exhaust gas recycling system 9 is located between the cylinder head 5 of the engine 2 and the intake manifold 7.

Advantageously, the system 9 is metallic, in order to resist the thermal stresses with which it is associated.

Figure 3 illustrates the engine 2 fully assembled to its components, and the system 9 for recycling exhaust gas. The exhaust gas recycling system 9 is disposed under the intake manifold 7, and occupies a very small space, making it possible to avoid setting up a specific arrangement in the enclosure of the engine 2, with the reduction in the volume of the engine 2 that would result.

As illustrated in Figure 4, the cylinder head 5 is hollowed with a plurality of intake ducts 10, and a plurality of exhaust ducts 11, the intake ducts 10 being connected to the system. 9 and the exhaust ducts 11 being connected to the exhaust manifold 8.

The intake manifold 7 comprises at its upper end a plenum 12. The plenum 12 is a volume allowing the accumulation of a gas, before introducing it into the intake pipes 13 extending from the plenum 12.

The plenum 12 optimizes the performance of the engine 2, while reducing fuel consumption.

In the present case, the gas is air, and its routing is symbolized in FIG. 4 by a series of hatched arrows (cloud of points), starting from the plenum 12, passing through the inlet pipes 13, the system 9, the inlet ducts 10, to finish in the combustion chamber 6.

The opening of an intake valve allows the introduction of a mixture of air and injected fuel, inside the combustion chamber 6.

Simultaneously, a piston sliding in the cylinder 4 will go down to reach its low position, commonly called bottom dead center (PMB).

The descent of the piston will cause the suction of the mixture of air and fuel in the combustion chamber 6.

Once the piston is in the down position, the inlet valve closes, and the piston rises, to compress the mixture of air and fuel.

When the piston reaches its upper position, called top dead center (TDC), a spark plug, connected to a high-voltage ignition system, produces a spark, causing the combustion of the mixture of air and fuel .

The hot gases produced by the combustion will then push the piston in the low position.

An exhaust valve will then open, to let the exhaust gas escape through the exhaust ducts 11.

The extraction of the exhaust gas is symbolized by a black arrow in FIG. 4.

As shown in Figure 5, the exhaust manifold 8 comprises a plurality of exhaust pipes 14, directly facing the exhaust ducts 11 of the cylinder head 5.

The exhaust manifold 8 makes it possible to circulate the exhaust gases to the exhaust system of the engine 2, or to route them to the system 9.

The exhaust pipes 14 join to form a vertically extending exhaust channel 15, from which a primary deflection pipe 16 is connected, for driving a portion of the exhaust gas through a channel 17 deflection, dug into the cylinder head 5.

The system 9 comprises a secondary deflection pipe 18 for conveying the exhaust gases from the cylinder head 5 to the system 9. The routing of the exhaust gases through the cylinder head 5 to the system 9 is symbolized by a series of black arrows in Figure 5.

As illustrated in FIG. 6, the system 9 comprises a connection support 19 enabling the secondary diversion pipe 18 to be connected to the system 9.

The support 19 link incorporates an air filter 20 to remove unwanted particles contained in the exhaust gas.

The support 19 comprises a linkage valve 21, to manage the flow of exhaust gas flowing through a passage 22 dug in the support 19 connection, this passage 22 to circulate the gases of exhaust inside a heat exchanger 23, as indicated by white arrows in Figure 6.

Advantageously, the valve 21 is located so that the arrival of the exhaust gas from the cylinder head 5 is under the valve 21, which avoids the clogging of the engine 2 .

The heat exchanger 23 allows to lower the temperature of the exhaust gas, before the formation of condensates that fall by gravity into a flow channel 24, the flow channel 24 dividing into several pipes 25 flow leading inside a plurality of profiles 26, as can be seen on the locket of Figure 4.

The circulation of the exhaust gas cooled by the exchanger is symbolized in Figure 6 by a series of hatched arrows (cells).

The heat exchanger 23 is a volume in which heat exchange takes place, these heat exchanges can be provided by internal pipes, associated with fins on the outside of the volume.

In addition, the heat exchanger 23 is arranged so as to form a slope 27 inside its volume, thus promoting the flow of the condensates, by gravity, to the profiles 26.

The profiles 26 are used to connect the cylinder head 5 to the intake manifold 7. Indeed, each section 26 faces an inlet duct 10 and an inlet pipe 13.

The system 9 described above has the following advantages.

The system 9 allows to provide the engine 2 a means of recycling its exhaust gas, without the need to change the general volume of the engine, or without the need to create a bulky space dedicated to the implementation of the system 9.

The system 9 can cool the exhaust gas, before injecting again into the engine 2, thus promoting the reduction of nitrogen oxides (NOx) in the combustion chamber 6.

The arrangement of the system 9 allows a continuous gravity flow of the condensates formed in the heat exchanger 23, and also reduces the clogging of the engine 2.

Claims (10)

An internal combustion engine (2) comprising: an engine block (3) having at least one cylinder (4); - a cylinder head (5) provided with at least one intake duct (10) and an exhaust duct (11), and defining with the cylinder (4) a combustion chamber (6); - an intake manifold (7) comprising at least one intake pipe (13) connected to a plenum (12); an exhaust manifold (8) connected to the exhaust duct (11); an exhaust gas recycling system (9) connected to the intake manifold (7) and the intake duct (10), the engine (2) being characterized in that the system (9) comprises an exchanger ( 23) heat, 2. Motor (2) according to claim 1, characterized in that the system (9) comprises at least one profile (26), integral with the heat exchanger (23) and connected, on the one hand, to the duct ( 10) and on the other hand to the intake pipe (13) 3. Engine (2) according to claim 2, characterized in that the system (9) comprises a flow channel (24) dug in the heat exchanger (23), extended by at least one pipe (25). flow opening into the profile (26). 4. Motor (2) according to any one of claims 1 to 3, characterized in that the system (9) comprises a support (T9) connecting, integral with the heat exchanger (23). 5. Motor (2) according to claim 4, characterized in that the system (9) comprises a valve (21), connected to the support (19) connecting, and adapted to manage the flow of exhaust gas in the heat exchanger (23). 6. Motor (2) according to any one of claims 4 or 5, characterized in that the yoke (5) is hollowed a channel (17) deflection. 7. Motor (2) according to claim 6, characterized in that the exhaust manifold (8) comprises a pipe (16) primary deflection, opening into the channel (17) deflection. 8. Motor (2) according to any one of claims 6 to 7, characterized in that the system (9) comprises a secondary pipe (18) of deflection, connected to the channel (17) of deflection and the support (19) link. 9. Motor (2) according to any one of claims 4 to 8, characterized in that the support (19) connection incorporates an air filter (20). 10. Motor (2) according to any one of claims 4 to 9, characterized in that the connecting support (19) is hollowed out with a passage (22), for the introduction of the exhaust gas into the exchanger (23) heat.