JP7636732B2 - Engine intake system structure - Google Patents

Description

The present invention relates to the structure of an exhaust recirculation gas introduction section in a vehicle intake passage.

Many engines installed in vehicles are equipped with an EGR device (exhaust gas recirculation device) to improve exhaust performance. The EGR device has an EGR passage that connects the exhaust passage and the intake passage, and recirculates a portion of the exhaust (EGR gas) from the exhaust passage to the intake passage, lowering the oxygen concentration in the intake air. This lowers the temperature inside the engine's combustion chamber and suppresses NOx emissions from the engine.

In the multi-cylinder engine described in Patent Document 1, an EGR passage is connected to a branch passage (branch pipe) of the intake manifold located at the most downstream of the intake passage, and EGR gas (exhaust gas recirculation) is introduced into each branch passage.

In addition, in Patent Document 1, multiple branch passages are arranged in parallel, an EGR passage is provided extending in a direction intersecting the branch passages, and gas supply ports to each branch passage are provided at the downstream end of the EGR passage, aligned in the extension direction of the EGR passage.

Furthermore, in Patent Document 1, the flow path cross-sectional area of the EGR passage just before connecting to each branch passage is configured to become smaller from the upstream side to the downstream side, making it easier for EGR gas to flow approximately evenly into each branch passage.

JP 2016-121540 A

However, in Patent Document 1, since EGR gas is supplied to the intake air in each branch passage, even if the flow path cross-sectional area of the EGR passage is set to become smaller toward the downstream side, when the engine operation fluctuates, for example, EGR gas may not flow appropriately into each branch passage in relation to the intake air volume, and the concentration of EGR gas in each cylinder may differ or fluctuate.

The present invention was made in consideration of these problems, and its purpose is to provide an engine intake system structure that can homogenize the concentration of exhaust recirculation gas in the intake air introduced into multiple cylinders.

In order to achieve the above object, the present invention provides an intake system structure for an engine, which includes a first surge tank in an intake passage, a branch passage for dividing intake air from the first surge tank to each cylinder, and an exhaust recirculation passage for recirculating a part of the exhaust gas to the intake passage as exhaust recirculation gas, the exhaust recirculation passage is connected to an introduction portion for introducing the exhaust recirculation gas into the intake passage upstream of the first surge tank, and includes a second surge tank for storing the exhaust recirculation gas having a smaller volume than the first surge tank, the first surge tank and the second surge tank are integrally formed , and the second surge tank is a pipe that closes the downstream end of the exhaust recirculation passage. the introduction section is formed by a tubular intake pipe having the intake passage therein and a peripheral wall forming part of the inner wall which is the downstream end side of the introduction passage section, the intake pipe being formed by an opening in the peripheral wall, the intake pipe being arranged offset to one side in the flow path width direction with respect to a center position in the flow path width direction of the introduction passage section, the intake pipe being connected to a tank inlet provided on the one side of the first surge tank, there being a gap between the inner wall on the other side of the flow path width direction of the introduction passage section and the peripheral wall, and the opening being provided in at least one of the peripheral walls in the flow path width direction of the introduction passage section, on a side of the peripheral wall in the direction of flow of the exhaust recirculation gas in the introduction passage section, or on the other side in the flow path width direction .

As a result, since the second surge tank is provided in the exhaust gas recirculation passage, the first surge tank and the second surge tank can be configured compactly, and even when the supply amount of exhaust gas recirculation gas is small, the exhaust gas recirculation gas is temporarily stored in the second surge tank before being introduced into the intake passage, the pressure of the exhaust gas recirculation gas is increased, and the exhaust gas recirculation gas is stably supplied to the intake passage upstream of the first surge tank, and the mixture of the intake air and the exhaust gas recirculation gas in the intake passage can be promoted. Furthermore, by temporarily storing the intake air mixed with the exhaust gas recirculation gas in the first surge tank, the mixture of the intake air and the exhaust gas recirculation gas is promoted in the first surge tank, and the exhaust gas recirculation gas in the intake air can be homogenized and supplied to each branch passage.
Also, the introduction portion for introducing the exhaust gas recirculated gas into the intake passage and the second surge tank can be realized with a simple structure.
The exhaust gas recirculation gas flowing through the introduction passage reaches the intake pipe, and flows around the gap between the inner wall of the introduction passage on one side in the flow path width direction and the peripheral wall of the intake pipe along the peripheral wall of the intake pipe. Then, the exhaust gas recirculation gas is introduced into the intake passage in the intake pipe from the opening, which generates a swirling flow of the exhaust gas recirculation gas in the intake pipe, and promotes mixing of the intake air and the exhaust gas recirculation gas.

Preferably, the first surge tank has a wall surface to which the intake passage is connected and which extends in a plane, and the second surge tank is formed along the wall surface of the first surge tank and surrounding the side surface of the intake passage.

This allows the second surge tank to be constructed simply and compactly along the wall surface of the first surge tank.

According to the engine intake system structure of the present invention, even when the supply amount of EGR gas is small, the EGR gas is temporarily stored in the second surge tank to increase the pressure of the EGR gas, and the EGR gas is stably supplied to the intake passage upstream of the first surge tank, thereby stabilizing the concentration of the EGR gas in the intake air. Furthermore, by temporarily storing the intake air mixed with the EGR gas in the first surge tank, the mixture of the intake air and the EGR gas is promoted in the first surge tank, and the EGR gas in the intake air can be homogenized and supplied uniformly to each branch passage.
This makes it possible to introduce intake air with a homogenized concentration of exhaust recirculation gas into each cylinder of the engine, thereby improving the effectiveness of exhaust recirculation.

1 is a schematic configuration diagram of a front part of a vehicle according to an embodiment of the present invention. FIG. 2 is a vertical cross-sectional view of an intake system accessory of the engine. FIG. 2 is a vertical cross-sectional view of an intake system accessory of the engine. FIG. 2 is a cross-sectional view of an intake system accessory of the engine. FIG. 11 is a vertical cross-sectional view of an intake system accessory according to another embodiment.

Hereinafter, an embodiment of the present invention will be described with reference to the drawings.
Fig. 1 is a schematic structural diagram of the front part of a vehicle 1 employing an intake system structure for an engine 3 according to an embodiment of the present invention. Fig. 2 is a vertical cross-sectional view of an intake system accessory disposed in front of the engine 3, as viewed from the left side in the vehicle width direction when mounted on the vehicle. Fig. 3 is a vertical cross-sectional view of the intake system accessory of the engine 3. Fig. 4 is a horizontal cross-sectional view of the intake system accessory of the engine 3. Fig. 3 is a cross-sectional view of the A-A portion shown in Fig. 2. Fig. 4 is a cross-sectional view of the B-B portion shown in Fig. 3.

As shown in Figure 1, a vehicle 1 incorporating the present invention is equipped with a power unit 4 including an engine 3 in an engine compartment 2 at the front. The vehicle 1 is a plug-in hybrid vehicle capable of operating in EV mode, series mode, and parallel mode.

The power unit 4 includes the engine 3 and a driving motor and a power generating motor generator (not shown). The driving motor and the power generating motor generator are arranged to the left of the engine 3 in the vehicle width direction. The power generating motor generator is also used as a starter motor for the engine 3.

The engine 3 is a four-cylinder engine, and is mounted transversely on the vehicle 1. An intake manifold 5 is provided on the front surface 3a of the engine 3, and an intake passage 6 is arranged therein. Meanwhile, an exhaust manifold 7 is provided on the rear surface side of the engine 3, and an exhaust passage 8 is arranged therein.

A throttle valve 10 is provided in the intake passage 6. A surge tank 11 (first surge tank) is provided between the throttle valve 10 in the intake passage 6 and the intake manifold 5.

The throttle valve 10 is located at the upper part of the front surface 3a of the engine 3, and is disposed between a branch pipe 12 (branch passage) connected to the second cylinder located in the center of the engine 3 in the vehicle width direction, and a branch pipe 12 connected to the third cylinder.

The surge tank 11 is provided along the front surface 3a of the engine 3 and is disposed below the throttle valve 10. Branch pipes 12 of the intake manifold 5 are connected from the surge tank 11 to each cylinder. The branch pipes 12 bend from the underside of the surge tank 11 toward the front of the vehicle, extend upward adjacent to the front side of the surge tank 11, and are connected to the intake ports 13 of each cylinder provided at the top of the front surface 3a of the engine 3.

On the other hand, a front catalyst 20 is provided in the exhaust passage 8 downstream of the exhaust manifold 7. A rear catalyst 21 is also provided in the exhaust passage 8 downstream of the front catalyst 20. The front catalyst 20 and the rear catalyst 21 are exhaust purification catalysts such as three-way catalysts. The front catalyst 20 is relatively small, and is arranged adjacent to the rear surface of the engine 3. The front catalyst 20 is arranged close to the engine 3 so that exhaust gas flows in from the engine 3 immediately, in order to improve exhaust purification performance during cold operation, such as immediately after the engine is started. The rear catalyst 21 is relatively large, and is arranged, for example, under the floor of the vehicle 1.

Furthermore, the engine 3 is equipped with an EGR device 30 (exhaust gas recirculation device). The EGR device 30 recirculates a portion of the exhaust gas back into the intake passage 6, thereby reducing the oxygen concentration in the intake air and suppressing the rise in temperature in the combustion chamber of the engine 3. This reduces NOx in the exhaust gas from the engine 3.

The EGR device 30 has an EGR passage 31 (exhaust gas recirculation passage) that connects the intake passage 6 and the exhaust passage 8, an EGR valve 34 that is interposed in the EGR passage 31 and adjusts the opening area of the EGR passage 31, and an EGR cooler 32 provided in the EGR passage 31.

The EGR cooler 32 is a water-cooled cooler that lowers the temperature of EGR gas (exhaust gas recirculation gas), which is exhaust gas passing through the EGR passage 31, and is disposed along the rear surface of the engine 3. By lowering the temperature of the EGR gas, the EGR cooler 32 further suppresses the rise in the temperature of the intake air into which the EGR gas has been introduced, thereby improving the NOx reduction effect of the EGR device 30.

The EGR passage 31 runs from near the exhaust outlet of the front catalyst 20, passes through the EGR cooler 32, extends upward from the rear left of the engine, wraps around to the front of the engine 3, passes through the EGR valve 34 located at the upper left of the engine, and is connected to the intake passage 6 between the throttle valve 10 and the surge tank 11.

2 to 4, an adapter 40 and an EGR ring 41 (inlet portion/intake pipe) are provided between the throttle valve 10 and the surge tank 11 as part of the intake passage 6 of the engine 3. The adapter 40 and the EGR ring 41 are cylindrical and have approximately the same diameter, with the lower end of the adapter 40 and the upper end of the EGR ring 41 connected and extending vertically along the front surface of the engine 3, the upper end of the adapter 40 connected to the throttle valve 10, and the lower end of the EGR ring 41 connected to a tank inlet 42 provided in the upper wall 11a of the surge tank 11.

The surge tank 11 is formed in a roughly rectangular box shape, with a tank inlet 42 provided at approximately the center in the left-right direction of the upper wall 11a and at the front of the vehicle.

Four tank discharge ports 43 are arranged side by side in the left-right direction at a position on the vehicle rear side of the lower wall 11b of the surge tank 11 corresponding to the number of cylinders of the engine 3. That is, in the surge tank 11, the tank inlet 42 and the tank discharge port 43 are arranged offset in the front-rear direction of the vehicle.

From each tank outlet 43 of the surge tank 11, a branch pipe 12 of the intake manifold 5 extends adjacent to the lower and front sides of the surge tank 11 toward the intake port 13 of the corresponding left and right cylinders.

The connection point between the EGR passage 31 in the EGR device 30 and the intake passage 6, i.e., the point where the EGR gas is introduced into the intake passage 6, is located between the throttle valve 10 and the surge tank 11.

The EGR passage 31 downstream of the EGR valve 34 extends along the upper wall 11a of the surge tank 11 from the left to the right in the vehicle width direction, and has an EGR inlet passage portion 45 (inlet passage portion, second surge tank) formed to surround the side of the EGR ring 41.

The EGR introduction passage 45 is tubular with a rectangular vertical cross section, has a front-to-rear width (e.g., a few cm) that is approximately the same as or slightly larger than the diameter of the EGR ring 41, and is rectangular in shape with the vertical width smaller than the horizontal width.

The EGR introduction passage 45 extends to the right in the vehicle width direction beyond the outer wall surface on the right side of the vehicle width direction of the EGR ring 41. In addition, the EGR introduction passage 45 is arranged offset toward the rear of the vehicle with respect to the axis of the EGR ring 41. Furthermore, a gap of, for example, about 1 cm is formed between the right inner wall surface at the tip side of the extension direction of the EGR introduction passage 45 (the forward side of the flow direction) and the right outer wall surface of the EGR ring 41, and between the rear inner wall surface of the EGR introduction passage 45 and the rear outer wall surface of the EGR ring 41. In addition, the front outer wall surface of the EGR ring 41 abuts against the front inner wall surface of the EGR introduction passage 45. That is, the internal space of the EGR introduction passage 45 faces the right, rear, and left parts of the outer wall surface (circumferential wall) of the EGR ring 41.

Furthermore, a ring hole 50 (opening) is provided at the rear of the outer wall surface of the EGR ring 41 facing the internal space of the EGR introduction passage 45, and a ring hole 51 (opening) is provided at the right side. As a result, the EGR gas that has passed through the EGR valve 34 is introduced from the EGR introduction passage 45 through the ring holes 50 and 51 into the intake passage in the EGR ring 41.

The vertical cross-sectional area, i.e., the flow area, of the EGR introduction passage 45 is larger than the flow area of the EGR passage 31 upstream of the EGR introduction passage 45. As a result, the EGR introduction passage 45 is adjacent to the upstream side of the ring holes 50, 51 of the EGR ring 41 and functions as a surge tank (second surge tank) that temporarily stores EGR gas.

In addition, the volume of the internal space that functions as a surge tank in the EGR introduction passage 45 is set to be smaller than the volume of the surge tank 11.

As described above, in this embodiment, the throttle valve 10 and intake manifold 5, which are intake system devices, are provided on the front surface 3a of the engine 3 mounted horizontally on the vehicle 1. In addition, a surge tank 11 is provided between the throttle valve 10 and the intake manifold 5. Branch pipes 12 of the intake manifold 5 are connected from the surge tank 11 to each cylinder, and the intake air is branched within the surge tank 11 and supplied to each cylinder via each branch pipe 12.

Furthermore, an EGR device 30 is provided which supplies EGR gas, which is a part of the exhaust gas, to the intake passage 6, and the EGR gas is introduced into the intake air at an EGR ring 41 provided in the intake passage 6 between the throttle valve 10 and the surge tank 11.

In addition, adjacent to the upstream side of the ring holes 50, 51 of the EGR ring 41, i.e., adjacent to the upstream side of the introduction position of EGR gas from the EGR passage 31 to the intake passage 6, the EGR passage 31 is provided with an EGR introduction passage portion 45 which functions as a surge tank for storing EGR gas.

Therefore, by temporarily storing the EGR gas in the EGR introduction passage 45 before introduction into the intake passage 6, the EGR gas can be stably supplied to the intake passage 6, and the mixing of the intake air and the exhaust gas recirculation gas in the intake passage 6 can be promoted. Furthermore, by temporarily storing the intake air mixed with the exhaust gas recirculation gas in the surge tank 11, the mixing of the intake air and the EGR gas in the surge tank 11 can be promoted, and the EGR gas in the intake air can be homogenized and supplied to each branch pipe 12 uniformly.

This allows intake air with a homogenized concentration of EGR gas to be introduced into each cylinder of the engine 3, thereby improving the effectiveness of the EGR device 30.

In addition, since the EGR introduction passage 45 has a smaller volume than the surge tank 11, even in engine operating conditions or transient operating conditions in which the amount of EGR gas supplied is small, the pressure of the EGR gas can be increased in the EGR introduction passage 45, and the EGR gas can be steadily supplied to the intake passage 6.

In addition, since the surge tank 11 and the EGR introduction passage 45 are formed integrally, the surge tank 11 and the second surge tank within the EGR introduction passage 45 can be configured compactly.

In addition, the surge tank 11 has an upper wall 11a to which the intake passage 6 is connected and which extends in a flat plane, and the EGR introduction passage portion 45 is formed along the upper wall 11a of the surge tank 11, so that the second surge tank can be constructed simply and compactly along the wall surface of the surge tank 11.

In addition, a tubular EGR introduction passage 45 with a closed tip is provided at the downstream end of the EGR passage 31, and the EGR ring 41 forms part of the inner wall on the tip side of this EGR introduction passage 45. In other words, by passing a tubular EGR ring 41 having ring holes 50, 51 through the EGR introduction passage 45 near the tip, an EGR gas introduction section that introduces EGR gas into the intake passage can be realized with a simple configuration.

The EGR ring 41 is offset toward the front of the vehicle from the center of the EGR introduction passage 45 in the flow path width direction (vehicle front-rear direction), and there is a gap between the inner wall of the EGR introduction passage 45 on the other side of the flow path width direction (vehicle rear side) and the peripheral wall of the EGR ring 41. The ring holes 50, 51 of the EGR ring 41 are provided on the right side and the rear side of the vehicle in the vehicle width direction of the peripheral wall of the EGR ring 41.

As a result, the EGR gas flowing through the EGR introduction passage 45 reaches the EGR ring 41 and flows around the gap between the inner wall of the EGR introduction passage 45 on the vehicle rear side and the EGR ring 41 along the outer wall of the EGR ring 41. The gas is then introduced into the intake passage 6 inside the EGR ring 41 through the ring holes 50, 51 of the EGR ring 41, generating a swirling flow of EGR gas in the intake passage 6 and promoting mixing of the intake air and the EGR gas.

Note that the present invention is not limited to the above embodiment. For example, in the above embodiment, the lower end of the EGR ring 41 is at approximately the same vertical position as the inner wall surface of the upper wall 11a of the surge tank 11. In contrast, as shown in FIG. 5, the EGR ring 41 may be extended downward so that the lower end 41a of the EGR ring 41 protrudes downward from the inner wall surface of the upper wall 11a of the surge tank 11.

In this way, by extending the EGR ring 41 downward, the distance from the ring holes 50, 51, which are the EGR gas introduction positions in the EGR ring 41, to the inside of the surge tank 11 is extended, and the mixing of the intake air and the EGR gas in the EGR ring 41 can be promoted. In addition, since the distance between the lower end of the EGR ring 41 and the bottom wall 11b of the surge tank 11 is shortened, the intake air containing the EGR gas that flows from the EGR ring 41 into the surge tank 11 is more likely to collide with the bottom wall 11b of the surge tank 11. This promotes the mixing of the EGR gas in the surge tank 11 and further suppresses the bias of the EGR gas concentration of the intake air supplied to each cylinder from each tank outlet 43.

Alternatively, in the above embodiment, the adapter 40 and the EGR ring 41 are separate structures, but the adapter 40 and the EGR ring 41 may be integrally formed.

In addition, in this embodiment, the present invention is applied to the engine 3 mounted on a plug-in hybrid vehicle, but it can also be applied to engines mounted on hybrid vehicles or gasoline vehicles, or engines other than those mounted on vehicles. The present invention can be widely applied to engines equipped with an EGR device.

3 engine 6 intake passage 11 surge tank (first surge tank)
12 Branch pipe (branch passage)
31 EGR passage (exhaust recirculation passage)
45 EGR introduction passage (introduction passage, second surge tank)
41 EGR ring (introduction part, intake pipe)
50, 51 Ring hole (opening)

Claims (2)

An intake system structure for an engine, comprising: a first surge tank in an intake passage; a branch passage for dividing intake air from the first surge tank to each cylinder; and an exhaust gas recirculation passage for recirculating a portion of exhaust gas to the intake passage,
the exhaust gas recirculation passage includes a second surge tank that is connected to an introduction portion that introduces the exhaust gas recirculation gas into the intake passage upstream of the first surge tank and that stores the exhaust gas recirculation gas and has a volume smaller than that of the first surge tank,
The first surge tank and the second surge tank are integrally formed,
the second surge tank is formed by a tubular introduction passage portion that closes a downstream end of the exhaust gas recirculation passage,
the introduction section has the intake passage therein, and a peripheral wall of the introduction section forms a part of an inner wall of the introduction passage section on the downstream end side, and is formed by a tubular intake pipe having an opening on the peripheral wall,
The intake pipe is
the inlet passage portion is offset in one direction in the width direction of the flow passage with respect to a center position in the width direction of the flow passage,
The first surge tank is connected to a tank inlet provided on the one side of the first surge tank,
a gap is provided between an inner wall of the introduction passage portion on the other side in the flow path width direction and the peripheral wall,
An intake system structure for an engine , characterized in that the opening is provided in at least a portion of the peripheral wall in a direction forward of the flow of the exhaust recirculation gas in the introduction passage portion, or on the other side in a width direction of the flow passage . the first surge tank has a wall surface to which the intake passage is connected and which extends in a plane;
2. The engine intake system structure according to claim 1, wherein the second surge tank is formed along the wall surface of the first surge tank and surrounding a side surface of the intake passage.

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