JP6420158B2 - Exhaust purification equipment - Google Patents

Description

  The present invention relates to an exhaust emission control device.

  There is known an exhaust emission control device including an oxidation catalyst and a filter arranged side by side in a straight section in an exhaust passage of an engine (Patent Document 1). In such an exhaust purification device, the upstream side oxidation catalyst and the downstream side filter are arranged close to each other, the exhaust gas reaches the filter at a high temperature, and the exhaust gas that has passed through the oxidation catalyst is Collides uniformly with the entire front surface (portion facing the upstream side). For this reason, good purification performance can be obtained.

JP 2001-98926 A

However, the exhaust gas purification device described in Patent Document 1 has an elongated shape because the oxidation catalyst and the filter are arranged in a straight line, and the place where the exhaust gas purification device can be mounted is limited.
An object of the present invention is to enable an exhaust purification device to be mounted in various places while suppressing a decrease in exhaust purification performance.

  One aspect of the present invention is a tubular member through which exhaust from an engine passes, and connects an upstream section, a downstream section located downstream of the upstream section, and a terminal end of the upstream section and a starting end of the downstream section. An exhaust path that is bent at an acute angle in the connection section, an upstream purification section that is disposed in the upstream section and that performs a treatment for purifying the exhaust gas that passes through the section, and is disposed in the downstream section. And a downstream side purification unit that performs a treatment for purifying the exhaust gas passing through the part, and a direction perpendicular to the direction of the upstream section and the direction of the downstream section is a width direction, A facing wall portion facing the upstream purification portion is formed, and a central portion in the width direction of the facing wall portion is an elongated region extending from the upstream side to the downstream side of the exhaust path, and is located outside the exhaust path. 1st protrusion part which becomes the shape which protruded toward That it is formed, to an exhaust gas control apparatus according to claim.

According to such a configuration, since the upstream side purification unit and the downstream side purification unit are arranged in a more integrated state, the exhaust purification device can be reduced in size.
Further, a portion connecting the upstream side purification unit and the downstream side purification unit in the exhaust path forms a sharp curve, and a path that passes through the outside of the curve and reaches the downstream side purification unit passes through the inside. Significantly longer than the route. That is, the exhaust gas passing outside the curve has a longer time to reach the downstream purification unit than the exhaust gas passing through the inside. For this reason, the inner part of the inlet surface of the downstream purification unit (the part facing the downstream side of the outer surface of the downstream purification unit) has a larger amount of exhaust collision than the outer part, and is uniform over the entire inlet surface. Since the exhaust does not collide, the purification performance of the downstream purification unit decreases.

  On the other hand, the 1st protrusion part is formed in the facing wall part arrange | positioned facing the upstream purification | cleaning part (in other words, it distribute | arranged along the outer side of this curve). For this reason, the exhaust gas passing outside the curve enters the space formed by the first projecting portion, and thereby the cross-sectional area of the exhaust gas flow path is narrowed. improves. As a result, it is possible to make the arrival time of the exhaust passing through the outer side to the downstream purification unit and the arrival time of the exhaust passing through the inner side approximately the same, and the exhaust is uniform over the entire inlet surface of the downstream purification unit. Therefore, it is possible to suppress a decrease in the purification performance of the downstream side purification unit.

Therefore, the exhaust gas purification device can be mounted at various locations while suppressing a decrease in the exhaust gas purification performance.
In the above configuration, the side where the upstream section is located in the downstream section is the inside, and the position closest to the inside in the portion facing the upstream side of the exhaust path in the downstream purification section is the inside end, and the upstream side The part of the purification unit that covers the exhaust passing through the part from the side is defined as a side, and the downstream purification unit has an end straight line extending through the inner end and extending along the downstream section. You may arrange | position so that it may cross | intersect the side part.

  According to such a configuration, the downstream purification unit is arranged in a state where the inner portion of the inlet surface faces the side surface of the upstream purification unit, and the downstream purification unit is further arranged in the upstream section. It can arrange | position in the state brought near to the upstream. Thereby, the length of the direction of the upstream section in the exhaust purification apparatus can be shortened, and the exhaust purification apparatus can be further downsized.

  Moreover, in the said structure, it is located in the area | region containing the downstream edge part of a 1st protrusion part in the center part of the width direction in a facing wall part, and has the shape which protruded toward the inside of an exhaust path. Two protrusions may be formed.

  According to such a configuration, the exhaust gas that has passed through the outside of the curve connecting the upstream side purification unit and the downstream side purification unit passes through the space formed by the first projecting portion provided on the facing wall portion, and the flow velocity It collides with a 2nd protrusion part in the state improved. As a result, the flow direction of the exhaust gas is inclined inward, and more exhaust gas can collide with the inner portion of the inlet surface of the downstream purification unit (the portion facing the side surface of the upstream purification unit on the inlet surface). . As a result, the exhaust gas uniformly collides with the entire inlet surface of the downstream side purification unit, and the deterioration of the purification performance of the downstream side purification unit can be suppressed.

  Further, in the above configuration, in the downstream side purification section, a portion through which the exhaust gas that has passed through the portion passes outside is defined as an exit surface, and the downstream section is located at a position close to the side where the upstream section is located at the end. In addition, a discharge port for discharging the exhaust to the outside of the exhaust purification device may be formed.

Here, in the exhaust gas purification apparatus, the side where the upstream section is located is the upper side, and the side where the end of the downstream section is located is the lower side.
When the discharge port is provided at the end of the downstream section, depending on the direction of the discharge port, the portion provided with the discharge port may have a shape protruding from the other portions. Further, the upstream section and the downstream section are arranged so as to intersect at an acute angle. For this reason, when the surface orthogonal to the downstream section is defined as the end of the downstream section, the surface forming the end is arranged in a state inclined with respect to the upstream section, and the side on the side (inside) where the upstream section is located on the surface forming the end The opposite side (outside) is the lower end of the exhaust gas purification device.

  Therefore, when the discharge port is formed at a position closer to the inside at the end of the upstream section, even if the portion provided with the discharge port has a shape that protrudes more than the other portions, the portion is the end of the upstream section. Protruding downward from the outside can be prevented. For this reason, it can suppress that it becomes long in the up-and-down direction of an exhaust-air-purification apparatus by having formed the exhaust port.

It is explanatory drawing which shows a mode that the exhaust gas purification apparatus and diesel engine of this embodiment of the state mounted in the vehicle were seen from the side. It is explanatory drawing which shows a mode that the exhaust gas purification apparatus and diesel engine of this embodiment of the state mounted in the vehicle were seen from the driver's seat side. It is a perspective view of the exhaust emission control device of this embodiment. It is a front view of the exhaust emission control device of this embodiment. It is a side view of the exhaust emission control device of this embodiment. It is explanatory drawing which represented typically the side cross section of the exhaust gas purification apparatus of this embodiment. It is sectional drawing of the connection part of the exhaust passage in the exhaust gas purification apparatus of this embodiment, and is VII-VII sectional drawing in FIG. It is a top view of the exhaust emission control device of this embodiment.

Hereinafter, an exemplary embodiment of the present invention will be described with reference to the drawings.
[Configuration of exhaust purification system]
The exhaust purification device 1 of the present embodiment is a device that purifies the exhaust of the diesel engine 2 mounted on the vehicle 3, and is disposed adjacent to the diesel engine 2 (FIGS. 1 and 2). Hereinafter, the right side and the left side from the driver's seat of the vehicle 3 toward the diesel engine 2 are simply referred to as the right side and the left side. The front side of the vehicle 3 is the front side, and the back side is the rear side. The exhaust purification device 1 can be disposed along the side surface of the diesel engine 2. In the present embodiment, the exhaust purification device 1 is disposed along the lower right portion of the rear surface of the diesel engine 2 as an example.

  The exhaust emission control device 1 includes an exhaust path 10, an inlet 11, and an outlet 12 (FIGS. 3 to 5). Further, an oxidation catalyst 16 and a filter 17 are provided inside the exhaust path 10 (FIG. 6).

The oxidation catalyst 16 oxidizes substances such as nitrogen monoxide (NO), carbon monoxide (CO), and hydrocarbon (HC) contained in the exhaust gas.
The filter 17 is arranged on the downstream side of the oxidation catalyst 16 and supplements and combusts PM (particulate matter) in the exhaust gas that has passed through the oxidation catalyst 16.

  The exhaust passage 10 is a tubular member that allows the exhaust from the diesel engine 2 to pass through, and has an upstream section 13, a connection section 14, and a downstream section 15, and has a shape bent at an acute angle in the connection section 14. ing.

  The inlet 11 is an opening formed at the start end of the exhaust path 10 (start end of the upstream section 13), and the exhaust discharged from the diesel engine 2 passes through the inlet 11 and enters the exhaust path 10.

  The exhaust port 12 is an opening formed at the end of the exhaust path 10 (the end of the downstream section 15), and the exhaust gas purified by the exhaust gas purification device 1 passes through the exhaust port 12 and is outside the exhaust gas purification device 1. To be discharged. An exhaust pipe extending rearward of the vehicle 3 is connected to the exhaust port 12, and the exhaust discharged from the exhaust port 12 enters the exhaust pipe.

The upstream section 13 is a linear section arranged along the first direction 13a that extends horizontally.
On the other hand, the downstream section 15 is a linear section that is positioned below the upstream section 13 and that is inclined downward with respect to the upstream section 13 (first direction 13a). That is, the downstream section 15 extends along the second direction 15a intersecting at an acute angle with respect to the first direction 13a (in other words, extends obliquely downward), and its start end 15b is the end of the upstream section 13 It is arranged so as to be adjacent to 13b.

The connection section 14 is a section that connects the terminal end 13 b of the upstream section 13 and the start end 15 b of the downstream section 15.
An oxidation catalyst 16 is disposed at the end portion of the upstream section 13, and all exhaust gas passing through the upstream section 13 passes through the oxidation catalyst 16. The oxidation catalyst 16 is placed along the first direction 13a. Of course, the arrangement position of the oxidation catalyst 16 is not limited to this, and may be arranged closer to the start end of the upstream section 13 than the arrangement position.

  Further, a filter 17 is disposed at the start end portion of the downstream section 15, and all exhaust gas that passes through the downstream section 15 passes through the filter 17. The filter 17 is arranged along the second direction 15a. Of course, the arrangement position of the filter 17 is not limited to this, and the filter 17 may be arranged closer to the end of the downstream section 15 than the arrangement position.

  Here, the inside of the curve formed by the upstream section 13, the connection section 14, and the downstream section 15 is described as the inside, and the outside of the curve is described as the outside. Further, a portion facing the upstream side on the outer surface of the filter 17 (portion where the exhaust gas passing through the filter 17 first passes) is defined as an inlet surface 17a, and a portion facing the downstream side of the outer surface (the exhaust gas passing through the filter 17 is A portion that passes when going outside is defined as an exit surface 17b. Further, the innermost portion of the entrance surface 17a (in other words, the end portion on the side where the upstream section 13 is located) is referred to as an inner end portion 17c.

  The filter 17 is arranged so that an end straight line 17 d that passes through the inner end 17 c and extends in the second direction 15 a (along the direction of the downstream section 15) intersects the side 16 b inside the oxidation catalyst 16. ing. In other words, the filter 17 is arranged so that the side portion 16b inside the oxidation catalyst 16 is positioned in front of the inner portion of the inlet surface 17a. The side portion 16b of the oxidation catalyst 16 is a portion that covers the exhaust gas passing through the oxidation catalyst 16 from the side.

  Further, a portion facing the downstream side of the outer surface of the oxidation catalyst 16 (portion through which the exhaust gas that has passed through the oxidation catalyst 16 passes outside) is defined as an outlet surface 16a. Further, a direction orthogonal to the first direction 13a and the second direction 15a is defined as a width direction.

  Moreover, the part which faces the exit surface 16a of the oxidation catalyst 16 among the wall surfaces which comprise the connection area 14 is made into the facing wall part 14a. Further, a straight line passing through an arbitrary position on the facing wall portion 14a, orthogonal to the facing wall portion 14a is defined as a reference line 14a-1, a straight line in the first direction 13a passing through the position is a first straight line, and the position passes through the position. The straight line in the second direction 15a is defined as the second straight line. Further, the angle formed between the reference line 14a-1 and the first straight line is defined as a first angle 13b, and the angle formed between the reference line 14a-1 and the second straight line is defined as a second angle 15b.

The facing wall portion 14a may be arranged such that the first angle 13b and the second angle 15b are the same or approximately the same size.
Moreover, the 1st protrusion part 14b and the 2nd protrusion part 14c are formed in the facing wall part 14a (FIG. 3, 5, 7, 8). The first projecting portion 14b and the second projecting portion 14c interfere with the flow of exhaust gas outside the connection section 14, so that the amount of exhaust gas that collides with each portion of the inlet surface 17a of the filter 17 is made uniform. . In other words, a similar amount of exhaust gas enters the inside of the filter 17 from each part of the inlet surface 17a due to the interference.

  Specifically, the first projecting portion 14b is formed at a central portion in the width direction of the facing wall portion 14a and is an elongated region extending from the upstream side to the downstream side of the exhaust path 10. It has a shape that protrudes toward the outside. In other words, the portions on both sides of the elongated region that extends from the upstream side to the downstream side of the exhaust path 10 located at the center portion in the width direction of the facing wall portion 14a protrude toward the inside of the exhaust path 10 ( It has a shape that has been crushed inside (FIGS. 5, 7, and 8).

  The second projecting portion 14c is a region including the downstream end portion of the first projecting portion 14b in the central portion in the width direction of the facing wall portion 14a (upstream side of the downstream end portion of the first projecting portion 14b. And a region extending downstream). The second protruding portion 14 c has a shape that gently protrudes toward the inside of the exhaust path 10. The second protrusion 14c has an arc shape when the second protrusion 14c is visually recognized along the width direction (FIGS. 5 and 8).

  Of course, the shape of the second protrusion 14c is not limited to this, and the second protrusion 14c may be formed in an elliptical shape or a polygonal shape when viewed from the side, You may form so that it may become the convex shape which consists of a curve and a straight line.

  Further, the innermost portion at the end of the downstream section 15 is defined as an inner portion. The discharge port 12 is arranged at the end in the width direction in the inner portion. In other words, the discharge port 12 is arranged at a rear position in the lower left corner of the exhaust purification device 1 that forms the end of the downstream section 15 (FIGS. 3 to 5).

  Of course, not limited to this, the discharge port 12 is formed between the center of the downstream section 15 at the end of the downstream section 15 (the center of the cross section perpendicular to the second direction 15a at the end of the downstream section 15) and the inner portion. May be. In addition to this, the discharge port 12 may be formed at the center of the downstream section 15 at the end of the downstream section 15, or may be formed at a position closer to the outside than the center at the end.

[Action, Effect]
According to the exhaust purification device 1 of the present embodiment, it is possible to avoid the exhaust purification device from having an elongated shape as in the case where the oxidation catalyst and the filter are arranged in a straight line. Further, compared to the case where the oxidation catalyst and the filter are arranged on the upstream side and the downstream side of the bending point in the exhaust path bent at 90 °, these can be arranged in a more aggregated state. Therefore, the exhaust emission control device 1 can be reduced in size.

  Further, the connection section 14 that connects the oxidation catalyst 16 and the filter 17 in the exhaust path 10 forms a sharp curve, and the exhaust that passes through the outside of the curve and reaches the filter 17 is exhaust that passes through the inside. Compared to, the travel distance is significantly increased. That is, the exhaust gas passing outside the curve has a longer time to reach the filter 17 than the exhaust gas passing through the inside. As a result, the amount of exhaust colliding with the inner portion of the inlet surface 17a of the filter 17 is larger than that of the outer portion, and the exhaust does not collide uniformly with the entire inlet surface 17a. End up.

  On the other hand, the 1st protrusion part 14b is formed in the facing wall part 14a distribute | arranged facing the oxidation catalyst 16 (in other words, it distribute | arranged along the outer side of this curve). For this reason, the exhaust gas passing outside the curve enters the space formed by the first projecting portion 14b, and thereby the cross-sectional area of the exhaust gas flow path is narrowed. Will improve. As a result, it is possible to make the arrival time of the exhaust passing through the outside reach the filter 17 and the arrival time of the exhaust passing through the inside, and the exhaust collides uniformly with the entire inlet surface 17a of the filter 17. As a result, a decrease in the purification performance of the filter 17 can be suppressed.

Therefore, the exhaust purification device 1 can be mounted in various places while suppressing a decrease in exhaust purification performance.
[Other Embodiments]
(1) In the exhaust purification device 1 of the present embodiment, the filter 17 passes through the inner end 17c, and the end straight line 17d extending in the second direction 15a intersects the side 16b inside the oxidation catalyst 16. (In other words, the filter 17 is arranged so that the side portion 16b on the inner side of the oxidation catalyst 16 is positioned in front of the inner portion of the inlet surface 17a).

  However, the present invention is not limited to this, and the filter 17 is arranged so that the end straight line 17d does not intersect the side part 16b on the inner side of the oxidation catalyst 16 (the side part 16b on the inner side of the oxidation catalyst 16 in front of the inner part of the inlet surface 17a May be arranged so that there is no position.

Even in such a case, the same effect can be obtained.
(2) In the present embodiment, the case where the present invention is applied to the exhaust purification device 1 that purifies exhaust from the diesel engine 2 mounted on the vehicle 3 is illustrated. However, the present invention is not limited to this, and the present invention can be applied to an exhaust purification device that purifies exhaust from various engines such as a gasoline engine.

  Further, in the present embodiment, the oxidation catalyst 16 is disposed on the upstream side of the exhaust path 10 of the exhaust purification device 1 and the filter 17 is disposed on the downstream side. However, the present invention is not limited to this, and an oxidation catalyst may be disposed at both the upstream position (position where the oxidation catalyst 16 is disposed) and the downstream position (position where the filter 17 is disposed) of the exhaust path 10. good. Further, a part for purifying the exhaust gas other than the oxidation catalyst 16 may be arranged at the upstream side position, and a part for purifying the exhaust gas other than the filter 17 may be arranged at the downstream side position.

Even in such a case, the same effect can be obtained.
(3) In addition, the aspect which abbreviate | omitted a part of structure of the said embodiment is also embodiment of this invention. Further, an aspect configured by appropriately combining the above embodiment and the modification is also an embodiment of the present invention. Moreover, all the aspects which can be considered in the limit which does not deviate from the essence of the invention specified by the wording described in the claims are the embodiments of the present invention.

[Correspondence with Claims]
The correspondence between the terms used in the description of the above embodiment and the terms used in the description of the claims is shown.

  The oxidation catalyst 16 corresponds to an example of an upstream purification unit, and the filter 17 corresponds to an example of a downstream purification unit.

  DESCRIPTION OF SYMBOLS 1 ... Exhaust gas purification device, 2 ... Diesel engine, 3 ... Vehicle, 10 ... Exhaust path, 11 ... Inlet, 12 ... Discharge port, 13 ... Upstream section, 14 ... Connection section, 14a ... Face-to-face wall part, 14b ... First protrusion Part, 14c ... 2nd protrusion part, 15 ... downstream area, 16 ... oxidation catalyst, 17 ... filter.

Claims (4)

A tubular member through which exhaust from the engine passes, and has an upstream section, a downstream section located on the downstream side of the upstream section, and a connection section connecting the end of the upstream section and the start end of the downstream section. And an exhaust path bent at an acute angle in the connection section;
An upstream side purification unit that is disposed in the upstream section and performs a treatment for purifying the exhaust gas passing through the part;
A downstream purification unit that is disposed in the downstream section and performs a treatment for purifying the exhaust gas passing through the part;
The direction orthogonal to the direction of the upstream section and the direction of the downstream section is the width direction,
In the connection section, a facing wall portion facing the upstream purification portion is formed,
A central portion of the facing wall portion in the width direction is an elongated region extending from the upstream side to the downstream side of the exhaust path and has a shape protruding toward the outside of the exhaust path. Part is formed,
An exhaust purification device characterized by the above. The exhaust emission control device according to claim 1,
The side where the upstream section is located in the downstream section is the inside,
In the portion facing the upstream side of the exhaust path in the downstream purification section, the position closest to the inside is the inner end,
In the upstream purification section, a portion that covers the exhaust gas passing through the part from the side is a side portion,
The downstream purification section is disposed so that an end straight line that passes through the inner end section and extends along the downstream section intersects the side section of the upstream purification section,
An exhaust purification device characterized by the above. The exhaust emission control device according to claim 1 or 2,
A second protrusion which is located in a region including the downstream end of the first protrusion and protrudes toward the inside of the exhaust path at the widthwise central portion of the facing wall portion. Part is formed,
An exhaust purification device characterized by the above. The exhaust emission control device according to any one of claims 1 to 3,
In the downstream purification section, a portion that passes when the exhaust gas that has passed through the portion exits to the outside is an exit surface,
In the downstream section, a discharge port for discharging the exhaust to the outside of the exhaust purification device is formed at a position close to the side where the upstream section is located at the end,
An exhaust purification device characterized by the above.