JP7293882B2 - engine exhaust structure - Google Patents

Description

The present invention relates to an engine exhaust structure.

An exhaust pipe of an engine is provided with a catalytic device for purifying exhaust gas. In order to purify the exhaust gas with the catalytic device, it is necessary to keep the temperature of the catalytic device above a predetermined temperature. On the other hand, if the temperature of the catalyst device becomes too high, there are problems such as deterioration of the catalyst. Therefore, temperature control of the catalytic converter is important.

Patent Document 1 discloses an exhaust structure including a front exhaust manifold for discharging exhaust gas from a plurality of front cylinders of a vertically mounted engine and a rear exhaust manifold for discharging exhaust gas from a plurality of rear cylinders of the engine. Are listed. A catalyst device is connected to each of the front and rear exhaust manifolds. Both catalytic converters are arranged laterally of the longitudinally mounted engine with a space therebetween. The upper parts of the front and rear exhaust manifolds and the front and rear catalyst devices are laterally covered with one insulator.

In the exhaust structure of Document 1, the insulator is used as a guide for the running wind, and the front and rear exhaust manifolds and the front and rear catalytic devices are evenly cooled by the running wind. For this purpose, the insulator has two running wind intakes aligned vertically at its front end. The interior of the insulator is partitioned by partition walls so that the running wind entering from the lower running wind intake hits the front exhaust manifold, and the running wind entering from the upper running wind intake hits the rear exhaust manifold. .

JP 2017-217995 A

By the way, when the vehicle is stopped, the temperature drops as the engine stops. As a result, the temperature of the catalytic device located on the side of the engine decreases as heat is taken away by the engine, which has a lower temperature. In that case, when the operation of the engine is restarted to run the vehicle, there is concern that the temperature of the catalyst device will be low and exhaust gas will not be purified efficiently.

Therefore, the present invention suppresses a decrease in the temperature of the catalyst device disposed on the side of the engine due to the heat being taken away by the low-temperature engine.

In order to solve the above problems, the present invention arranges a heat insulating insulator between the engine and the catalyst device.

The engine exhaust structure disclosed herein is:
a catalyst device disposed on the side of an engine for purifying exhaust gas discharged from the engine;
An insulator for heat shielding arranged between the engine and the catalyst device,
The insulator includes a vertical wall portion extending along the side surface of the catalyst device so as to form a vertical wall between the engine and the catalyst device, and the vertical wall portion extends along the side surface of the catalyst device. provided with a bent portion that is bent from the engine side to the end face side of the catalyst device ,
The insulator is a lower insulator arranged between the engine and the lower part of the catalyst device,
Furthermore, an upper insulator for heat shielding is arranged so as to form a vertical wall between the engine and the upper part of the catalyst device,
A cover for covering the catalyst device from above extends from the upper end of the upper insulator .

According to this structure, the insulator shields the radiant heat from the catalytic device toward the engine. Therefore, the catalyst device is restrained from being deprived of heat by the engine. Moreover, since the end portion of the vertical wall portion of the insulator is provided with a curved portion that is bent from the engine side to the end surface side of the catalyst device, the escape of heat from the catalyst device to the engine side is further suppressed. Good for temperature retention. Further, the insulator suppresses heat transfer from the upper portion of the catalyst device to the engine side. Furthermore, although the hot air heated by the catalytic converter rises along the lower insulator and the upper insulator, the hot air stays under the cover, which is advantageous for maintaining the temperature of the catalytic converter.

The engine exhaust structure disclosed herein is:
a catalyst device disposed on the side of an engine for purifying exhaust gas discharged from the engine;
An insulator for heat shielding arranged between the engine and the catalyst device,
The insulator includes a vertical wall portion extending along the side surface of the catalyst device so as to form a vertical wall between the engine and the catalyst device, and the vertical wall portion extends along the side surface of the catalyst device. provided with a bent portion that is bent from the engine side to the end face side of the catalyst device,
a plate-shaped bracket projecting from an end of the engine toward an end of the catalyst device for supporting the catalyst device on the engine;
The plate-like bracket has a vertical plate surface and blocks at least a portion between the engine and the catalyst device.

According to this structure, the insulator shields the radiant heat from the catalytic device toward the engine. Therefore, the catalyst device is restrained from being deprived of heat by the engine. Moreover, since the end portion of the vertical wall portion of the insulator is provided with a curved portion that is bent from the engine side to the end surface side of the catalyst device, the escape of heat from the catalyst device to the engine side is further suppressed. Good for temperature retention. Furthermore, since the plate-like bracket suppresses the escape of heat from between the engine and the catalytic converter, it is advantageous in maintaining the temperature of the catalytic converter.

The engine exhaust structure disclosed herein is:
a catalyst device disposed on the side of an engine for purifying exhaust gas discharged from the engine;
An insulator for heat shielding arranged between the engine and the catalyst device,
The insulator includes a vertical wall portion extending along the side surface of the catalyst device so as to form a vertical wall between the engine and the catalyst device, and the vertical wall portion extends along the side surface of the catalyst device. provided with a bent portion that is bent from the engine side to the end face side of the catalyst device,
The insulator is a lower insulator arranged between the engine and the lower part of the catalyst device,
Furthermore, an upper insulator for heat shielding is arranged so as to form a vertical wall between the engine and the upper part of the catalyst device,
a cover extending from the upper end of the upper insulator to cover the catalyst device from above;
a plate-shaped bracket projecting from an end of the engine toward an end of the catalyst device for supporting the catalyst device on the engine;
The plate-like bracket has a vertical plate surface and blocks at least a portion between the engine and the catalyst device.

According to this structure, the insulator shields the radiant heat from the catalytic device toward the engine. Therefore, the catalyst device is restrained from being deprived of heat by the engine. Moreover, since the end portion of the vertical wall portion of the insulator is provided with a curved portion that is bent from the engine side to the end surface side of the catalyst device, the escape of heat from the catalyst device to the engine side is further suppressed. Good for temperature retention. Further, the insulator suppresses heat transfer from the upper portion of the catalyst device to the engine side. Furthermore, although the hot air heated by the catalytic converter rises along the lower insulator and the upper insulator, the hot air stays under the cover, which is advantageous for maintaining the temperature of the catalytic converter. Furthermore, since the plate-like bracket suppresses the escape of heat from between the engine and the catalytic converter, it is advantageous in maintaining the temperature of the catalytic converter.

In one embodiment, the catalyst device includes an upstream catalyst that extends laterally in the upper portion of the engine in the longitudinal direction of the engine, and an upstream catalyst that is connected to the upstream catalyst and extends laterally in the lower portion of the engine in the longitudinal direction of the engine. a downstream catalyst extending to
The lower insulator is arranged between the lower part of the engine and the downstream catalyst,
The upper insulator is arranged between the upper part of the engine and the upstream catalyst,
A heat insulating insulator is arranged on the opposite side of the plate-shaped bracket with the upstream catalyst interposed therebetween and covers the upstream catalyst from the opposite side.

Therefore, the insulator suppresses heat from escaping from the catalyst device to the opposite side of the plate-shaped bracket, which is advantageous for maintaining the temperature of the catalyst device.

According to the present invention, a heat insulating insulator is provided between the engine and the catalyst device, and the insulator extends along the side surface of the catalyst device so as to form a vertical wall between the engine and the catalyst device. Since the extended end portion is provided with a curved portion that is bent from the engine side to the end face side of the catalyst device, heat is suppressed from being taken from the catalyst device to the engine side, and the temperature of the catalyst device is maintained. be advantageous to Therefore, it is advantageous for the treatment of exhaust gas when the operation of the engine is restarted.

1 is a schematic side view of the front of a vehicle; FIG. Front view of the front part of the vehicle. 1 is a front view of an engine and a catalyst device; FIG. FIG. 2 is a side view of the engine and catalyst device; FIG. 2 is a side view of the engine excluding exhaust system components including a catalyst device; FIG. 2 is a front view of the engine excluding exhaust system components including a catalyst device;

EMBODIMENT OF THE INVENTION Hereinafter, the form for implementing this invention is demonstrated based on drawing. The following description of preferred embodiments is merely exemplary in nature and is not intended to limit the invention, its applications or uses.

<Schematic configuration of the front part of the vehicle>
In the front part of a vehicle 1 shown in FIG. 1, 2 is an engine room covered with a bonnet 3, 4 is an in-line multi-cylinder engine, and 5 is a dash panel that separates the engine room 2 from the vehicle compartment. The engine 4 is a longitudinally mounted engine mounted on the vehicle 1 in a posture in which the cylinder row direction parallel to the crankshaft extends in the vehicle front-rear direction. A transmission 6 is arranged behind the engine 4 . An undercover 7 is provided in the engine room 2 to cover the lower surface of the engine 4 from below.

As shown in FIG. 2 , a running wind introduction port 8 for introducing running wind of the vehicle 1 into the engine room 2 is open at the front end of the vehicle 1 . A front grille (not shown) is attached to the running wind inlet 8 .

<Structure of engine and its exhaust system>
As shown in FIG. 3, a catalyst device 9 is arranged close to the engine 4 on the side of the engine 4 (on the side where the exhaust manifold exists (left side in FIG. 3)) when viewed from the front side of the vehicle. The catalyst device 9 treats the exhaust gas discharged from the engine 4 . As shown in FIG. 4 , the catalyst device 9 comprises an upstream catalyst 11 and a downstream catalyst 12 .

The upstream catalyst 11 of this example is an oxidation catalyst (DOC) that oxidizes and purifies HC and CO in the exhaust gas. The upstream catalyst 11 has its axis extending in the upper side of the engine 4, i.e., in the side of the cylinder head 13 in the direction of the row of cylinders of the engine 4 (vehicle front-rear direction). flow. The engine 4 and the upstream catalyst 11 are arranged in the width direction of the vehicle 1 . As is clear from FIG. 3 , the width of the upstream catalyst 11 is narrower than the width of the engine 4 . The upstream end of the upstream catalyst 11 is connected (directly connected) to the exhaust gas outlet of the turbine 15 of the turbocharger 14 . The exhaust gas inlet portion 15a of the turbine 15 is connected to the collective portion 16 of each of the two exhaust manifolds of the engine 4 shown in FIG. One of the two exhaust manifolds discharges exhaust gases from a plurality of cylinders and the other discharges exhaust gases from a remaining plurality of cylinders. Both exhaust manifolds are incorporated inside the cylinder head 13 of the engine 4 .

The downstream side catalyst 12 of this example is a catalytic particulate filter (DPF) that collects and burns off particulates in the exhaust gas. The downstream side catalyst 12 is arranged below the upstream side catalyst 11, and its axis extends in the direction of the cylinder row of the engine 4 along the lower side of the engine 4, that is, the side of the cylinder block 17, and exhaust gas flows toward the rear of the vehicle. The engine 4 and the downstream catalyst 12 are arranged in the width direction of the vehicle 1 . As is clear from FIG. 3 , the width of the downstream side catalyst 12 is narrower than the width of the engine 4 . As shown in FIG. 4 , the downstream end of the upstream catalyst 11 and the upstream end of the downstream catalyst 12 are connected on the front end side of the engine 4 . Therefore, the exhaust gas flows through the upstream side catalyst 11 toward the front of the vehicle, makes a U-turn at the junction of the upstream side catalyst 11 and the downstream side catalyst 12, and flows through the downstream side catalyst 12 toward the rear of the vehicle.

An EGR cooler 22 of an EGR device that recirculates part of the exhaust gas to the intake system of the engine 4 is connected upright to an exhaust pipe 21 that continues to the downstream end of the downstream side catalyst 12 . The EGR cooler 22 cools the exhaust gases that are recirculated to the intake system. An EGR pipe 24 that guides the exhaust gas to the compressor 23 side of the turbocharger 14 is connected to the upper end of the EGR cooler 22 . The exhaust pipe 21 is connected via a flexible tube 25 to an exhaust pipe 26 further downstream.

<Insulator and bracket>
A plurality of heat insulating insulators are provided between the engine 4 and the catalytic device 9 . That is, as shown in FIGS. 3 to 5, the upper insulator 31 is arranged between the cylinder head 13 of the engine 4 and the upstream catalyst 11 so as to form a vertical wall. A lower insulator 32 is arranged to form a vertical wall between the cylinder block 17 of the engine 4 and the downstream side catalyst 12 .

3 to 6, the insulators 31, 32, 35, 36 and the plate-like bracket 34 are indicated by thick lines to clarify their outer shapes.

The upper insulator 31 extends along the side surface of the upstream catalyst 11 between the cylinder head 13 and the upstream catalyst 11 in the cylinder row direction (vehicle front-rear direction) of the engine 4 . The upper insulator 31 extends substantially over the entire length of the upstream catalyst 11 . The upper insulator 31 is provided with a cover 33 projecting from its upper end over the upstream catalyst 11 . The cover 33 covers the upstream catalyst 11 from above.

The lower insulator 32 has a vertical wall portion extending between the cylinder block 17 and the downstream side catalyst 12 along the side surface of the downstream side catalyst 12 in the cylinder row direction (vehicle front-rear direction) of the engine 4 . The lower insulator 32 extends substantially over the entire length of the downstream side catalyst 12 . As shown in FIG. 3 , a front end surface (vehicle front side end surface) of the downstream side catalyst 12 is attached to the engine front end side end portion of the vertical wall portion of the lower insulator 32 extending in the cylinder row direction of the engine 4 . A bent portion 32a is provided that is bent to the side. The bent portion 32a is formed over a range from the upper end to the lower end of the lower insulator 32 so as to partially cover the front end face of the downstream side catalyst 12 from the vehicle front side. As shown in FIG. 2 , at least the upper portion of the curved portion 32 a at the front end of the lower insulator 32 faces the wind introduction port 8 of the engine room 2 .

As shown in FIG. 3 , a plate-like bracket 34 that supports the upstream catalyst 11 on the engine 4 is fixed to the front end of the cylinder head 4 of the engine 4 . As shown in FIGS. 5 and 6, the plate-like bracket 34 has a vertical portion 34a on its plate surface. The lower part between them is blocked from the front side of the vehicle.

As shown in FIGS. 4 and 5, two insulators 35 and 36 for shielding heat are arranged on the opposite side of the plate-like bracket 34 with the upstream catalyst 11 interposed therebetween, that is, on the rear side of the vehicle. . That is, the rear upper insulator 35 is arranged on the upper half circumference side of the turbocharger 14 , and the rear lower insulator 36 is arranged on the lower half circumference side of the turbocharger 14 .

As shown in FIG. 6, the rear upper insulator 35 extends in the width direction of the vehicle with its plate surface vertical and covers the upper side of the upstream catalyst 11 from the rear side of the vehicle. The rear lower insulator 36 has a portion extending in the width direction of the vehicle with its plate surface vertical, and covers the lower side of the upstream catalyst 11 from the rear side of the vehicle. Insulators 35 and 36 are supported by turbocharger 14 .

3 to 6, 37 is an oil pan of the engine 4. As shown in FIG.

<Effect of insulator and bracket>
[Driving vehicle]
While the vehicle 1 is running, high-temperature exhaust gas flows to the catalyst device 9 due to the operation of the engine 4, so the catalyst device 9 needs to be cooled. The transmission 6 also needs to be cooled in order to ensure reliability of its operation.

In the front structure of the vehicle 1 , part of the running wind introduced into the engine room 2 from the running wind introduction port 8 is directed toward the engine 4 and the catalyst device 9 . Since the running wind is blocked by the engine 4 and the catalyst device 9, it flows to the rear of the vehicle along the outer peripheral surfaces of both so as to detour outward.

Here, between the engine 4 and the downstream side catalyst 12 of the catalyst device 9, a lower insulator 32 is arranged so as to form a vertical wall separating the two, and the front end portion of the lower insulator 32 extends from between the two to the front of the vehicle. is coming. Therefore, the running wind, which hits both the engine 4 and the downstream catalyst 12 as a whole, is divided by the lower insulator 32 into the engine 4 side and the downstream catalyst 12 side, and flows toward the rear of the vehicle. Since the transmission 6 is arranged behind the engine 4 , the running wind flowing toward the engine 4 mainly flows toward the transmission 6 .

Since the width of the downstream side catalyst 12 is narrower than the width of the engine 4 in the branched flow of the running air, the amount of running air flowing toward the engine 4 side and toward the transmission 6 is greater than the amount of running air flowing toward the downstream side catalyst 12 side. In particular, since the curved portion 32a at the front end of the lower insulator 32 directs the flow of running air toward the engine 4, the amount of running air flowing toward the engine 4 increases.

A portion of the running wind that flows toward the engine 4 bypasses the engine 4 to the intake system side (the right side in FIGS. 2 and 3) and flows toward the rear of the vehicle. Since the temperature of the intake system is lower than that of the exhaust system in which the catalyst device 8 is provided, the running wind receives less heat from the intake system. That is, the running wind flowing to the engine 4 side does not rise in temperature so much and goes to the transmission 6 in a relatively low temperature state. Further, the lower insulator 32 prevents the running wind that flows toward the downstream catalyst 12 and is heated by the heat of the exhaust system from mixing with the running wind that flows toward the engine 4 . Further, the undercover 7 prevents the running wind flowing toward the engine 4 from escaping downward from the vehicle. As a result, the running wind that flows toward the engine 4 tends to flow toward the transmission 6 .

In this way, the amount of traveling air flowing toward the engine 4 side and toward the transmission 6 increases, and the temperature of the traveling air is relatively low, which is advantageous for cooling the transmission 6 . On the other hand, the downstream side catalyst 12 is also cooled by the low-temperature running wind introduced from the running wind introduction port 8, although the amount of wind is small.

Further, since the plate-shaped bracket 34 is provided so as to block the gap between the engine 4 and the upstream side catalyst 11 from the front side of the vehicle, the amount of traveling air flowing through the gap to the rear of the vehicle is reduced. When the running wind passing through this gap is heated by the engine 4 and the upstream side catalyst 11 and its temperature rises, the amount of the passing wind is reduced, so that the temperature rise of the transmission 6 is suppressed.

[Vehicle stop]
When the vehicle 1 stops from running, the catalyst device 9 cools down due to heat dissipation since the hot exhaust gas is no longer supplied as the engine 4 stops. If the catalyst device 9 cools down to the activation temperature or less of the catalyst, purification performance of the exhaust gas discharged from the engine 4 when the operation of the vehicle 1 is restarted deteriorates. The problem is that the radiant heat of the catalyst device 9 is transmitted to the engine 4, that is, the catalyst device 9 is deprived of heat by the engine 4 and cooled down.

In contrast, according to the exhaust structure of the above embodiment, the upper insulator 31 blocks the radiant heat from the upstream side catalyst 11 toward the engine 4 . That is, the radiant heat is not taken away by the engine 4 and stays between the upstream side catalyst 11 and the upper insulator 31, so cooling of the upstream side catalyst 11 is suppressed.

Similarly, the lower insulator 32 shields the radiant heat from the downstream side catalyst 12 toward the engine 4 . That is, the radiant heat is not taken away by the engine 4 and stays between the downstream side catalyst 12 and the lower insulator 32, so cooling of the downstream side catalyst 12 is suppressed. In particular, since the front end portion of the lower insulator 32 is provided with a bent portion 32a bent from the side of the engine 4 to the side of the front end surface of the downstream side catalyst 12, heat can escape from the side of the downstream side catalyst 12 to the side of the engine 4. This is further suppressed, which is advantageous for maintaining the temperature of the downstream side catalyst 12 .

Also, the hot air heated by the downstream side catalyst 12 rises along the lower insulator 32 , and further rises along the upper insulator 31 together with the hot air heated by the upstream side catalyst 11 . On the other hand, since the upper insulator 31 is provided with the cover 33 that covers the upstream side catalyst 11 from above, the hot air stays under the cover 33 to suppress its diffusion. Therefore, it is advantageous to maintain the temperatures of the upstream side catalyst 11 and the downstream side catalyst 12 .

In addition, a plate-like bracket 34 is arranged so as to block the gap between the engine 4 and the upstream catalyst 11 from the front side of the vehicle. Therefore, the plate-shaped bracket 34 suppresses heat from escaping to the front of the vehicle through this gap, which is advantageous for maintaining the temperatures of the upstream side catalyst 11 and the downstream side catalyst 12 .

Furthermore, the rear upper insulator 35 and the rear lower insulator 36 suppress heat from escaping from around the upstream side catalyst 11 to the rear of the vehicle, which is advantageous for maintaining the temperatures of the upstream side catalyst 11 and the downstream side catalyst 12 .

Therefore, when the operation of the vehicle 1, that is, the operation of the engine 4 is restarted, the deterioration of the exhaust gas processing efficiency of the upstream and downstream catalysts 11 and 12 is suppressed, or the catalysts 11 and 12 are activated early. to process the exhaust gas.

Although the engine 4 in the above-described embodiment is vertically mounted, even if the engine is horizontally mounted with the cylinder row direction arranged in the width direction of the vehicle 1, the arrangement structure of the insulators or brackets described above can be used. It is possible to keep the catalyst device 9 warm while the vehicle is stopped.

Further, in the lower insulator 32 of the above-described embodiment, the vertical wall portion extending along the catalyst 12 and the curved portion 32a are integrated, but the vertical wall portion and the curved portion may be separate bodies.

Moreover, although it is not essential to provide the upper insulator 31, in the case where it is provided, the upper insulator 31 and the cover 33 may be separated.

Reference Signs List 1 vehicle 2 engine room 4 engine 6 transmission 7 undercover 8 running wind inlet 9 catalyst device 11 upstream catalyst 12 downstream catalyst 31 upper insulator 32 lower insulator 32a bent portion 33 cover 34 plate-like bracket 35 rear upper insulator 36 rear lower side insulator

Claims (4)

a catalyst device disposed on the side of an engine for purifying exhaust gas discharged from the engine;
An insulator for heat shielding arranged between the engine and the catalyst device,
The insulator includes a vertical wall portion extending along the side surface of the catalyst device so as to form a vertical wall between the engine and the catalyst device, and the vertical wall portion extends along the side surface of the catalyst device. A bent portion bent from the engine side to the end surface side of the catalyst device is provided at the end ,
The insulator is a lower insulator arranged between the engine and the lower part of the catalyst device,
Furthermore, an upper insulator for heat shielding is arranged so as to form a vertical wall between the engine and the upper part of the catalyst device,
An exhaust structure for an engine , wherein a cover for covering the catalyst device from above extends from an upper end of the upper insulator . a catalyst device disposed on the side of an engine for purifying exhaust gas discharged from the engine;
An insulator for heat shielding arranged between the engine and the catalyst device,
The insulator includes a vertical wall portion extending along the side surface of the catalyst device so as to form a vertical wall between the engine and the catalyst device, and the vertical wall portion extends along the side surface of the catalyst device. A bent portion bent from the engine side to the end surface side of the catalyst device is provided at the end,
a plate-shaped bracket projecting from an end of the engine toward an end of the catalyst device for supporting the catalyst device on the engine;
The exhaust structure for an engine, wherein the plate-like bracket has a vertical plate surface and blocks at least a portion between the engine and the catalyst device. a catalyst device disposed on the side of an engine for purifying exhaust gas discharged from the engine;
An insulator for heat shielding arranged between the engine and the catalyst device,
The insulator includes a vertical wall portion extending along the side surface of the catalyst device so as to form a vertical wall between the engine and the catalyst device, and the vertical wall portion extends along the side surface of the catalyst device. A bent portion bent from the engine side to the end surface side of the catalyst device is provided at the end,
The insulator is a lower insulator arranged between the engine and the lower part of the catalyst device,
Furthermore, an upper insulator for heat shielding is arranged so as to form a vertical wall between the engine and the upper part of the catalyst device,
a cover extending from the upper end of the upper insulator to cover the catalyst device from above;
a plate-shaped bracket projecting from an end of the engine toward an end of the catalyst device for supporting the catalyst device on the engine;
The exhaust structure for an engine, wherein the plate-like bracket has a vertical plate surface and blocks at least a portion between the engine and the catalyst device. In claim 3 ,
The catalyst device includes an upstream catalyst extending in the longitudinal direction of the upper part of the engine, and a downstream catalyst connected to the upstream catalyst and extending in the longitudinal direction of the lower part of the engine. and
The lower insulator is arranged between the lower part of the engine and the downstream catalyst,
The upper insulator is arranged between the upper part of the engine and the upstream catalyst,
An exhaust structure for an engine, characterized by comprising a heat insulating insulator disposed on the opposite side of the plate-shaped bracket with the upstream catalyst therebetween and covering the surroundings of the upstream catalyst from the opposite side. .

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