DE102008044364A1 - Additive distribution plate in an exhaust passage - Google Patents

Abstract

A distribution plate (4) distributes an aqueous urea solution injected into an exhaust passage for an engine at a position upstream of an exhaust gas purification device. The distribution plate (4) is provided to extend in a direction crossing a direction in which the exhaust passage extends. Spared portions (42) recessed toward a downstream side in an exhaust gas flow direction are provided on a surface (40) of the distribution plate (4). Impact pieces (43) are provided above the corresponding recessed portions (42). Each baffle piece (43) is inclined to extend in a direction substantially perpendicular to a direction in which the aqueous urea solution is injected. Connecting portions (44) are provided above the respective impact pieces (43). Exhaust gas flows from an area upstream of the distribution plate (4) to an area downstream of the distribution plate (4) through the connection portions (44).

Description

BACKGROUND OF THE INVENTION

1. Field of the invention

The The invention relates to an additive distribution plate containing an additive distributed at a position upstream of an exhaust gas purification device, which is arranged in the exhaust passage, in an exhaust passage a machine was injected.

2. Description of the stand of the technique

exhaust, that delivered by a machine and in particular a diesel engine contains generally pollutants produced by incineration such as nitrogen oxides (hereinafter referred to as NOx ), such as nitric oxide. To an air pollution too avoid, it is strongly required, the amount of these pollutants, which are emitted by the diesel engine to reduce. NOx can work together with exhaust from a gasoline engine with direct injection be dispensed in the gas depending on an operating condition injected directly into a combustion chamber. That's why it's also necessary to reduce the amount of pollutants from the gasoline engine be delivered with direct injection.

Consequently becomes an emission control device, which is a three-way catalyst includes, arranged in an exhaust passage to NOx to clean, which is discharged together with the exhaust gas.

however can the exhaust gas purification device including the Three-way catalyst depending on the type of machine do not sufficiently clean the NOx. If, for example, a diesel engine used with lean combustion, the exhaust gas contains excess Oxygen, and therefore a fuel component (HC) reacts easily with the oxygen (that is, the fuel component (HC) is easily burned). Thus, it is for the three-way catalyst difficult to purify the NOx sufficiently.

For example, Japanese Patent Application Publication No. is described 2007-77957 a technology in which an exhaust gas purifying apparatus including a catalyst for selective reduction of NOx is disposed in an exhaust passage; a mixer consisting of a stamped metal or the like is disposed at a position upstream of the exhaust gas purification device in a manner that the mixer is arranged to extend in a direction crossing a direction in which the exhaust gas passage extends; and an aqueous urea solution is injected to a surface (that is, a surface on an upstream side in the exhaust gas flow direction) of the mixer to disperse the aqueous urea solution in the exhaust gas. Thus, the NOx in the exhaust gas is effectively purified.

There according to the technique described above Additive distribution plate such as the mixer arranged is to extend in the direction that crosses the direction, in which the exhaust gas passage extends, the additive, that to the surface of the additive distribution plate is injected, such as the aqueous urea solution, because of the collision between the aqueous urea solution and the additive distribution plate atomizes and vaporizes. However, part of the additive may be on the additive distribution plate attach, and may at the time of the collision between the additive and the additive distribution plate, a liquid film form. The additive that forms the liquid film, may drip down because of the weight of the additive. Consequently can the additive to a wall surface of the exhaust gas passage drip and adhere to it.

SUMMARY OF THE INVENTION

The The invention provides an additive distribution plate in an exhaust passage ready, which reliably drops one drop of an additive, which adheres to the additive distribution plate and a liquid film trains, prevents downwards.

One The first aspect of the invention relates to an additive distribution plate, which distributes an additive that is at a position upstream an exhaust gas purification device disposed in the exhaust gas passage is injected into an exhaust passage of a machine. The additive distribution plate has a movement restricting portion, at a surface of the additive distribution plate is formed, and the movement of the additive to the Surface of the additive distribution plate limited. The additive distribution plate is arranged in one direction extending, which crosses a direction in which the exhaust passage extends so that the additive injected into the exhaust passage is used, with a surface of the additive distribution plate clashes.

Of the Motion restriction portion may be a recessed portion be to one in an exhaust gas flow direction, in the exhaust gas flows downstream side is omitted. The recessed portion may be in the additive distribution plate extend in a lateral direction.

With The arrangement described above is the additive distribution plate arranged to extend in the direction that the direction crosses, in which the exhaust passage extends, and the recessed Portion that is downstream in the exhaust gas flow direction Side down recessed is on a surface the additive distribution plate arranged in the lateral To extend direction. If a part of the additive that belongs to the surface of the additive distribution plate injected became attached to the surface of the additive distribution plate attached, and at a time of collision between the additive and the additive distribution plate, a liquid film forms, and the additive that the liquid film due to the weight of the additive along the surface the additive distribution plate drips down, becomes the additive therefore taken up by the recessed section. Corresponding becomes the admixture received by the recessed portion heated by the exhaust gas and is evaporated. That's why it is possible, the possibility that the additive from the additive distribution plate to the wall surface the exhaust passage drips, and on the wall surface of the Exhaust gas passage adheres to effectively reduce.

The Additive distribution plate may also have a baffle section which is above the movement restricting portion is arranged, and which is inclined to move in one direction substantially extending at right angles to a direction in which the additive is injected into the exhaust passage; and may be a connecting section have, which is located above the baffle section, and through an exhaust gas from an area upstream of the additive distribution plate to an area downstream of the additive distribution plate flows in the exhaust gas flow direction.

With the arrangement bounces the additive that to the surface the additive distribution plate is injected with the baffle section together in the direction that is substantially perpendicular to the Direction is in which the baffle section extends. Consequently because of the clash between the additive and the Baffle section the biggest energy on the additive applied. Therefore, the additive is using the large impact energy atomized into finer components. The atomized additive is determined by the flow of the Exhaust gas through the connecting portion above the baffle section to the downstream in the exhaust gas flow direction Page guided. Thus, it is possible the efficiency to improve the distribution of the atomised additive. If a part of the additive adheres to the baffle section and at a time of the collision between the additive and the Impact portion forms a liquid film, and the additive, which forms the liquid film, because of the weight of the additive along the surface of the additive distribution plate drips down, the additive is through the movement restriction section added. This through the movement restriction section absorbed additive is heated by exhaust gas and is evaporated. That is why it is possible to that the additive from the additive distribution plate to the Wall surface of the exhaust gas passage drips, and at the Wall surface of the exhaust gas passage adheres effectively to reduce.

Of the Restriction section may be in the lateral Direction from one end portion to the other end portion of Extend additive distribution plate. The movement restriction section may be in the lateral direction to a central portion of the movement restricting portion be inclined in such a manner that the central portion of the movement restricting portion in the lateral direction below the end portions of the movement restricting portion is positioned in the lateral direction. In this case will the entire admixture, which is a liquid film an entire side surface of the surface of the Forming distribution plate that is above the movement restricting section, to extend in the lateral direction, through the movement restricting section taken up in the lateral direction from one end section to another end portion of the additive distribution plate extends, and formed long in the lateral direction is. As a result, the additive caused by the movement restricting section is received, which formed long in the lateral direction is, because of the weight of the additive from the sides of the movement restriction section in the lateral direction to the central portion of the movement restricting portion guided in the lateral direction, and thus becomes the Additive in the central portion of the movement restriction portion collected in the lateral direction. Accordingly, the additive, in the middle portion of the movement restricting portion in FIG the lateral direction is collected, using effectively of the exhaust gas that evaporates near the middle section flows, and whose temperature is higher than that of the exhaust gas that is near the wall surface of the Exhaust gas passage flows.

In addition, the additive distribution plate may be inclined toward a center portion of the additive distribution plate disposed near a center of the exhaust passage, in such a manner that the center portion of the additive distribution plate is at a most downstream Position is arranged in the exhaust gas flow direction in the additive distribution plate. In this case, after the exhaust gas which has flowed to the additive distribution plate has collided with the additive distribution plate, the exhaust gas flows from an edge portion of the additive distribution plate to the center portion of the additive distribution plate because of the collision between the exhaust gas and the additive distribution plate. Therefore, the additive which adheres to the additive distribution plate and forms a liquid film is guided along the flow direction of the exhaust gas from the edge portion of the additive distribution plate to the center portion of the additive distribution plate located near the center of the exhaust passage. Accordingly, the additive is collected in the center portion of the additive distribution plate. Thus, the additive collected in the center portion of the additive distribution plate is effectively vaporized by the exhaust gas whose temperature is highest at a position near the center of the exhaust passage.

The Additive distribution plate can in a vertical direction in a manner to a central portion of the additive distribution plate be inclined that the central portion of the additive distribution plate in the vertical direction in the exhaust gas flow direction downstream of the end portions of the additive distribution plate is positioned in the vertical direction. Also, the Movement restricting portion at the central portion the additive distribution plate formed in the vertical direction be.

The Additive distribution plate may be in a substantially vertical Direction. The additive distribution plate can in a Way inclined backwards that an upper one End portion of the additive distribution plate downstream a lower end portion of the additive distribution plate in the exhaust gas flow direction is positioned.

As has been described above, the recessed portion which to the downstream in the exhaust gas flow direction Side is inclined, on the surface of the additive distribution plate arranged to extend in the lateral direction. If the additive itself at a time of clash between the additive and the additive distribution plate on the additive distribution plate adheres and forms a liquid film, and the Additive that forms the liquid film, after dripping down, therefore, the additive is left in the Section added. The admixture that by the recessed Section was recorded, is heated by the exhaust gas and is evaporated. Thus, it is possible to prevent that the additive from the additive distribution plate to the wall surface the exhaust passage drips, and effectively the adhesion of the additive to suppress on the wall surface of the exhaust gas passage.

BRIEF DESCRIPTION OF THE DRAWINGS

The above-described and other objects, features and advantages The invention will become apparent from the following description of exemplary Embodiments with reference to the attached Drawings are clear where used the same reference numerals to represent the same elements, and in which:

1 is a sectional view of a portion of an exhaust passage, in which a distribution plate according to a first embodiment of the invention is arranged, in which the sectional view is viewed from the side;

2 is a perspective view of the distribution plate, which is viewed obliquely from the front;

3 is a perspective view of a distribution plate according to a second embodiment of the invention, which is viewed obliquely from the front;

4 is a perspective view of a distribution plate according to a third embodiment of the invention, which is viewed obliquely from the front;

5 is a perspective view of a distribution plate according to a fourth embodiment of the invention, which is viewed obliquely from the front;

6 is a perspective view of a distribution plate according to a fifth embodiment of the invention, which is viewed obliquely from the front;

7 is a sectional view of a portion of an exhaust passage, in which a distribution plate is arranged according to a sixth embodiment of the invention, in which the sectional view is viewed from the side;

8th is a longitudinal sectional view of the distribution plate, which is viewed from the side;

9 is a sectional view of a portion of an exhaust passage, in which a distribution plate is arranged according to a seventh embodiment of the invention, and the sectional view is viewed from the side;

10 is a perspective view of the distribution plate, which is viewed obliquely from the front;

11 is a longitudinal sectional view of the distribution plate, which is viewed from the side;

12 is a perspective view of a distribution plate according to an eighth embodiment of the invention, which is viewed obliquely from the front; and

13 is a longitudinal sectional view of the distribution plate, which is viewed from the side;

DETAILED DESCRIPTION THE EMBODIMENTS

in the Embodiments of the invention will be referred to below described on the drawings.

1 is an exhaust passage for a diesel engine of a vehicle (an example of the engine) in which an additive distribution plate construction according to a first embodiment of the invention is used. In 1 is an exhaust gas purification device 2 in an exhaust passage 1 arranged. The exhaust gas purification device 2 has a catalyst 21 for selective reduction, which selectively causes nitrogen oxides (NOx) in an exhaust gas to react even with the presence of oxygen with a reducing agent (an example of the admixture). The catalyst 21 for selective reduction is within a mat 12 in a section 11 large diameter of the exhaust gas passage 1 arranged, which has a large diameter. The section 11 large diameter is with another section of the exhaust passage 1 through a horn-shaped, arched section 13 connected in the radial direction of the exhaust gas passage 1 from a downstream side in an exhaust gas flowing direction (hereinafter referred to as "exhaust gas flow direction") to an upstream side, in this case, the exhaust gas passing through in the exhaust gas becomes 1 flows along the arched section 13 in the radial direction of the exhaust gas passage 1 at an upstream in the exhaust gas flow direction portion of the curved portion 13 led to the outside. The flow of the exhaust gas is from the curved section 13 at a downstream portion of the domed portion 13 separated in the exhaust gas flow direction. Thus, the flow of the exhaust gas becomes the mat 12 (To a side outside in a radial direction of the section 11 large diameter) effectively through the arched section 13 distracted. The exhaust gas flow direction may be substantially parallel to a direction in which the exhaust gas passage 1 extends.

The catalyst 21 for selective reduction reduces and purifies the NO x in the exhaust gas passing through the exhaust gas using a reducing agent 1 flows. In the catalyst 21 For selective reduction, for example, a zeolite-active ingredient is supported by a monolithic catalyst carrier having a honeycomb-shaped cross section made of cordierite ceramics or Fe-Cr-Al-based heat-resistant steel. When the active ingredient carried by the catalytic carrier receives the reducing agent, the active ingredient is activated to effectively convert the NOx into harmless substances. In this case, a method becomes NOx using the selection reduction catalyst 21 to reduce, referred to as catalytically selective reduction (SCR). In particular, the SCR using urea as the reducing agent is referred to as urea SCR.

An injector 3 is in the exhaust gas flow direction upstream of the exhaust gas purification device 2 (of the catalyst 21 for selective reduction). The injector 3 An aqueous urea solution (an example of the additive) injects, serving as a reducing agent. The injector 3 is on a peripheral wall of the exhaust gas passage 1 arranged in an upper position. The aqueous urea solution is discharged from an injection port 31 the injector 3 to one in the exhaust gas flow direction upstream of the catalyst 21 supplied for selective reduction area. The aqueous urea solution and compressed air become the injector 3 fed. The aqueous urea solution is passed through the injection port 31 atomized and injected. The injection opening 31 the injector 3 is from the upper portion at the peripheral wall portion of the exhaust passage 1 directed obliquely to a downstream in the exhaust gas flow direction side. The injection opening 31 the injector 3 namely, is at a suitable angle (for example, substantially 45 degrees) with respect to an axis m of the exhaust gas passage 1 directed obliquely to the downstream in the exhaust gas flow direction side. In this case, the aqueous urea solution is stored in a storage tank. The aqueous urea solution is supplied to the injection nozzle via a supply pipe made of synthetic resin 3 fed. In 1 Dotted arrows indicate the flow of the exhaust gas when the atomized aqueous urea solution is dispersed in the exhaust gas, and solid arrows indicate the flow of the exhaust gas before the aqueous urea solution is dispersed.

The aqueous urea solution coming from the injection port 31 the injector 3 is injected because of the heat of the exhaust gas in the exhaust passage 1 hydrolyzed, and thus becomes easy Ammonia generated. The generated ammonia reacts in the catalyst 21 for selective reduction with NOx contained in the exhaust gas, and thus the ammonia is converted to water and a harmless gas. The aqueous urea solution is an aqueous solution which is produced by dissolving solid urea or urea powder in water. The aqueous urea solution is stored in the storage tank and becomes the injection nozzle via the supply pipe 3 fed. In addition to the aqueous urea solution, an aqueous ammonia solution and an aqueous hydrocarbon solution may be used as the reducing agent (examples of the additive) discharged from the injection nozzle 3 be injected.

A distribution plate 4 is directly downstream of the injector 3 in the exhaust gas flow direction (that is, upstream of the selection reduction catalyst 21 in the exhaust gas flow direction). The distribution plate 4 works as an additive distribution plate and distributes the aqueous urea solution coming from the injector 3 in the exhaust passage 1 was injected into the exhaust. In other words, the distribution plate 4 between an upstream side where the injector 31 is arranged, and a downstream side, where the exhaust gas purification device 2 is arranged in the exhaust passage 1 provided. How out 1 and 2 is apparent, is the distribution plate 4 arranged to extend in a direction crossing the direction in which the exhaust passage 1 extends. Even more accurate is the distribution plate 4 in a substantially vertical direction. If the distribution plate 4 in the exhaust gas flow direction from an upstream side, the distribution plate is located 4 essentially rectangular. The distribution plate 4 is using flange sections 41 with a wall surface of the exhaust gas passage 1 connected in a radial direction from corners of the distribution plate 4 after protrude.

Saved sections 42 are on a surface 40 (that is, an upstream surface in the exhaust gas flow direction) of the distribution plate 4 educated. The four recessed sections 42 are arranged at equal intervals in a vertical direction in four rows each, which are arranged in a lateral direction. The four recessed sections 42 are arranged at equal intervals in the lateral direction in each of the four rows arranged in the vertical direction. Each recessed section 42 is to the downstream side in the exhaust gas flow direction (that is, in 1 to the right side) recessed. Each recessed section 42 extends in a side direction of a vehicle body (a substantially horizontal direction). plump pieces 43 and connection openings 44 are above the corresponding recessed sections 42 arranged. The baffle pieces 43 work as impact sections. Every baffle piece 43 extends in a direction substantially perpendicular to a direction in which the aqueous urea solution from the injection port 31 the injector 3 in the exhaust passage 1 is injected. The exhaust gas flows through the connecting portions 44 from an area upstream of the distribution plate 4 to an area downstream of the distribution plate 4 in the exhaust gas flow direction. Even more accurate is every baffle piece 43 around a lower edge of the corresponding connection section 44 inclined to the downstream side in the exhaust gas flow direction in a manner that the impact piece 43 extends in the direction substantially perpendicular to the direction in which the urea aqueous solution from the injection port 31 the injector 3 in the exhaust passage 1 is injected. straightening plates 45 are at upper edges of the corresponding connection sections 44 arranged. Each straightening plate 45 is around the top edge of the corresponding connection section 44 inclined to the downstream side in the exhaust gas flow direction. After the aqueous urea solution with each baffle piece 43 and the urea aqueous solution has been atomized, the atomized aqueous urea solution becomes uniform along the flow of the exhaust gas through the corresponding straightening plate 45 to the exhaust gas purification device 2 guided. Every baffle piece 43 and the straightening plates 45 By cutting and bending a section of the distribution plate 4 educated. Each connection section 44 is formed by forming the corresponding baffle piece 43 and the corresponding straightening plate 45 by cutting and bending portions of the distribution plate 4 to be open. Because every recessed section 42 from the surface 40 the distribution plate 4 recessed to the downstream side in the exhaust gas flow direction, the recessed portion functions 42 as a rib, the rigidity of the distribution plate 4 elevated.

In this case, determine a recessed section 42 , a baffle piece 43 , a connecting section 44 and a straightening plate 45 a set, and the sets are regularly in the vertical direction (the substantially vertical direction) and the side direction (the substantially horizontal direction) of the distribution plate 4 arranged. The length of each recessed section 42 in the lateral direction is slightly longer than the length of each connecting portion 44 in the lateral direction of the vehicle body.

Thus, in the first embodiment, the recessed portions 42 on the surface 40 the distribution plate 4 educated. Everyone out saved section 42 is recessed in the exhaust gas flow direction to the downstream side. Each recessed section 42 extends in the lateral direction. In addition, the bumpers 43 at corresponding recessed sections 42 arranged. Every baffle piece 43 is inclined to extend in the direction which is substantially orthogonal in the direction in which the aqueous urea solution from the injection port 31 is injected from. The connecting sections 44 are above the corresponding impact pieces 43 arranged. The exhaust gas flows through the connecting portions 44 from the area upstream of the distribution plate 4 to the area downstream of the distribution plate 4 in the exhaust gas flow direction. If the aqueous urea solution, leading to the surface 40 the distribution plate 4 is injected with the surface 40 the distribution plate 4 because of the collision between the aqueous urea solution and the distribution plate, therefore, an energy is applied to the aqueous urea solution 4 applied. Thus, the aqueous urea solution is atomized into fine components using the impact energy. Also, the aqueous urea solution bounces with each baffle 43 in the direction substantially perpendicular to the direction in which the baffle piece 43 extends, together. Therefore, because of the collision between the aqueous urea solution and each baffle 43 a greater energy is applied to the aqueous urea solution. The aqueous urea solution is atomized into finer components using the large impact energy. Accordingly, the atomized aqueous urea solution passes through the corresponding connecting section 43 above each baffle piece 43 passed through the flow of the exhaust gas in the exhaust gas flow direction to the downstream side. Thus, it is possible to increase the efficiency of distribution of the atomized aqueous urea solution.

If any part of the aqueous urea solution, which is to the surface 40 the distribution plate 4 is injected on the surface 40 the distribution plate 4 and at a time of impact between the aqueous urea solution and the distribution plate 4 forms a liquid film, and the aqueous urea solution, which forms the liquid film, along the surface 40 Because of the weight of the aqueous urea solution dripping down, the aqueous urea solution will pass through each recessed section 42 added. If any part of the aqueous urea solution, which is added to each baffle 43 is injected on the surface of the baffle piece 43 and at a time of impact between the aqueous urea solution and the baffle 43 forming a liquid film, the aqueous urea solution forming the liquid film also drips along the surface 40 the distribution plate 4 from the surface of the baffle piece 43 because of the weight of the aqueous urea solution, and the aqueous urea solution is passing through the respective recessed portion 42 added. Accordingly, the aqueous urea solution passing through each recessed section 42 is absorbed, heated by the exhaust gas and is evaporated. Thus, it is possible to prevent the aqueous urea solution from the distribution plate 4 to the wall surface of the exhaust gas passage 1 drips, and adhering the aqueous urea solution at a lower portion of the exhaust passage 1 effectively suppress.

A second embodiment of the invention will be described with reference to FIG 3 described.

In In the second embodiment, the arrangement of the recessed Section changed. The sections of the arrangement, the in the second embodiment, not the recessed portion are the same as in the first embodiment. therefore These will be the same as those of the first embodiment Sections indicated by the same reference numerals, and the detailed description thereof is omitted.

How out 3 is apparent, namely, in the second embodiment, four connecting portions 44 at regular intervals in the lateral direction in each of four rows arranged in the vertical direction. A recessed section 46 extends continuously in the lateral direction from one end portion to the other end portion of the distribution plate 4 in the lateral direction below the connecting sections 44 in each of the four rows arranged in the vertical direction. A vertical section 40a that extends in the vertical direction is between each pair of the connecting portions 44 provided adjacent to each other in the lateral direction. In this case, every recessed section is 46 trained, every vertical section 40a to divide in the vertical direction.

If the aqueous urea solution, which is on the surface 40 the distribution plate 4 adheres, and which forms a liquid film when the aqueous urea solution to the surface 40 the distribution plate 4 injected, and those with the surface 40 bounces, along the surface 40 Because of the weight of the aqueous urea solution dripping down, in the second embodiment, accordingly, the urea aqueous solution dropped downward is passed through each recessed portion 46 added. If in this case the aqueous urea solution, which at each vertical section 40a between each pair of connecting sections 44 adjacent to each other tet, and which forms the liquid film, along the vertical section 40a dripping down, the aqueous urea solution also passes through each recessed section 46 added. Thus, the aqueous urea solution is separated from each vertical section 40a the distribution plate 4 drips down, also reliably through each recessed section 46 added. The aqueous urea solution passing through each recessed section 46 is absorbed, is heated by exhaust gas and is evaporated. Thus, it is possible to reliably prevent the aqueous urea solution from becoming the wall surface of the exhaust gas passage 1 dripping, and adhering the aqueous urea solution to the lower portion of the exhaust passage 1 more effective to suppress.

Next, a third embodiment of the invention will be described with reference to FIG 4 described. In the third embodiment, the arrangement of the recessed portion is changed. The portions of the assembly not related to the recessed portion in the third embodiment are the same as those in the first embodiment. Therefore, those portions and those corresponding to those of the first embodiment will be denoted by the same reference numerals, and their detailed description will be omitted.

How out 4 is apparent, namely, in the third embodiment, the four connecting portions 44 at equal intervals in the lateral direction in each of four rows arranged in the vertical direction. A recessed section 47 Continually extends in the lateral direction from one end portion to the other end portion of the distribution plate 4 in the lateral direction below the connecting sections 44 in each of the four rows arranged in the vertical direction. The ends of each recessed section 47 in the lateral direction are at respective ends of the distribution plate 4 open to the outside in the lateral direction (to the exhaust gas passage 1 HIN).

Accordingly, in the third embodiment, the aqueous urea solution passing through each recessed portion 47 is absorbed, heated by the exhaust gas and is evaporated. In addition, the vaporized aqueous urea solution becomes active from the ends of each recessed portion 47 in the side direction along the flow of the exhaust gas in the exhaust gas flow direction to the downstream side. Thus, it is possible to reliably prevent the aqueous urea solution from becoming the wall surface of the exhaust gas passage 1 dripping, and adhering the aqueous urea solution to the lower portion of the exhaust passage 1 effectively suppress.

Next, a fourth embodiment of the invention will be described with reference to FIG 5 described.

In The fourth embodiment is the arrangement of the recessed Section changed. The sections of the arrangement, the not the recessed portion in the fourth embodiment are the same as those in the first embodiment. Therefore, these and those of the first embodiment corresponding sections are denoted by the same reference numerals, and their detailed description is omitted.

How out 5 is apparent, namely in the fourth embodiment, the four connecting portions 44 at regular intervals in the lateral direction in each of four rows arranged in the vertical direction. A recessed section 48 extends continuously in the lateral direction from one end portion to the other end portion of the distribution plate 4 in the lateral direction, below the connecting sections 44 in each of the four rows arranged in the vertical direction. Each recessed section 48 is at a center portion of the recessed portion 48 inclined in the lateral direction in a manner such that the central portion of the recessed portion 48 in the lateral direction below the end portions of the recessed portion 48 is positioned in the lateral direction, and the recessed portion 48 has a substantially V-shape. In this case, the temperature of the exhaust gas that enters the exhaust passage 1 flows at a position near the center portion of each recessed portion 48 higher in the lateral direction than in a position near the end points of the recessed portion 48 in the lateral direction.

Accordingly, in the fourth embodiment, the whole urea aqueous solution containing the liquid film on an entire side surface of the surface 40 the distribution plate 4 formed above each recessed portion to extend in the lateral direction, through the recessed portion 48 taken from one end portion to the other end portion of the distribution plate 4 extends in the lateral direction, and is long in the lateral direction. As a result, the aqueous urea solution passing through each recessed section 48 taken long in the lateral direction from both sides of each recessed portion 48 in the lateral direction to the central portion of the recessed portion 48 in the lateral direction because of the weight of the aqueous urea solution, and thus the aqueous urea solution becomes in the central portion of the recessed portion 48 collected in the lateral direction. Accordingly, the aqueous urea solution discharged in the central portion of each saved section 48 in the side direction, using the exhaust gas flowing near the center portion and having a temperature higher than that of the exhaust gas near the wall surface of the exhaust gas passage 1 flows, effectively evaporates. In each of the above-described embodiments, the recessed portion, which is recessed toward the downstream side in the exhaust gas flow direction, is formed on the surface of the distribution plate to receive the urea aqueous solution adhering to the surface of the distribution plate. However, the invention is not limited to this recessed portion. For example, instead of the recessed portion, a projecting portion may be arranged to receive the urea aqueous solution adhering to the surface of the distribution plate. It is possible to restrict the movement of the aqueous urea solution along the surface 40 because of the weight of the aqueous urea solution is dripped down, and to prevent the urea aqueous solution from dripping to the wall surface of the exhaust passage in which the protruding portion is provided on the distribution plate, as well as by providing the recessed portion on the distribution plate.

Next, a fifth embodiment of the invention will be described with reference to FIG 6 described.

In The fifth embodiment is the arrangement the baffle changed, and the straightening plate is omitted. The arrangement of the fifth embodiment is the same as the arrangement of the first embodiment, except that the arrangement of the baffle is changed, and that the straightening plate in the fifth embodiment is omitted. That's why the same and the first Embodiment corresponding sections with the same Numeral designates and their detailed description is omitted.

How out 6 is apparent, namely, in the fifth embodiment, each baffle piece 49 by cutting a section of the distribution plate 4 and bending the portion of the distribution plate 4 at a lower edge of the corresponding connection portion 44 educated. Every baffle piece 49 is around the lower edge of the corresponding connection section 44 inclined in the exhaust gas flow direction to the downstream side. In this case, each baffle extends 49 in the direction substantially perpendicular to the direction in which the aqueous urea solution from the injection port 31 the injector 3 in the exhaust passage 1 is injected. In the fifth embodiment, the straightening plate is formed by cutting a portion of the distribution plate 4 and bending the portion of the distribution plate 4 at the upper edge of the connecting portion 44 formed in the first embodiment is omitted.

slots 49a that extend in the lateral direction are in each baffle piece 49 formed at three positions in the vertical direction (in 6 are only four impact pieces 49 in an upper end of the distribution plate 4 denoted by the same reference numerals). Every slot 49a has a small width (for example, the width of 3 mm or less), so that the aqueous urea solution that adheres to the surface of each baffle 49 adheres to the surface of the baffle piece 49 through one through the slot 49a generated surface tension is retained. If in this case the aqueous urea solution, which is on the surface of each baffle 49 adheres, and those on the surface of the baffle piece 49 is retained by the surface tension passing through each slot 49a is generated by the heat of the exhaust gas is evaporated, the aqueous urea solution through each slot 49a guided to the downstream side in the exhaust gas flow direction.

Thus, in the above-described fifth embodiment, the aqueous urea solution adhered to each baffle 49 adheres and forms the liquid film on the surface of the baffle 49 through the through each slot 49a retained surface tension retained. This suppresses the dripping down of the aqueous urea solution due to the weight of the urea aqueous solution. Thus, the aqueous urea solution that is at the surface of each baffle 49 by the surface tension passing through each slot 49a is retained, vaporized by the exhaust gas and the vaporized aqueous urea solution is uniformly through each slot 49a guided in the exhaust gas flow direction to the downstream side.

In addition, the slots 49a in every baffle piece 49 are formed, it is possible to decrease the flow passage area of the exhaust gas passage 1 decrease, through which the exhaust gas flows (that is, a decrease in the sectional area of the exhaust gas passage 1 ). Accordingly, the effective surface of the exhaust gas passage 1 , through which the exhaust gas flows, increases. Thus, it is possible to increase the back pressure downstream of the distribution plate 4 in the exhaust gas flow direction.

Next, a sixth embodiment of the invention will be described with reference to FIG 7 and 8th described.

In the sixth embodiment, the An changed the order of the distribution plate. The portions of the assembly which do not relate to the recessed portion in the sixth embodiment are the same as those in the first embodiment. Therefore, those portions and those corresponding to those of the first embodiment will be denoted by the same reference numerals, and their detailed description will be omitted.

How out 7 and 8th Namely, in the sixth embodiment, a distribution plate 5 (the additive distribution plate) inclined to extend in the direction substantially perpendicular to the direction in which the aqueous urea solution from the injection port 31 the injector 3 in the exhaust passage 1 is injected. Even more accurate is the distribution plate 5 in the exhaust gas flow direction toward the downstream side at a suitable angle (for example, about 60 degrees) with respect to the axis m of the exhaust gas passage 1 tilted backwards. The distribution plate 5 is essentially rectangular when the distribution plate 5 in the exhaust gas flow direction from the upstream side. The distribution plate 5 is on the wall surface of the exhaust gas passage 1 using a flange section 51 attached in the radial direction of corners of the distribution plate 5 protruding outwards.

How out 8th can be seen, are also recessed sections 52 on a surface 50 (That is, on a surface at the upstream in the exhaust gas flow direction side) of the distribution plate 5 educated. The four recessed sections 52 are provided at equal intervals in the vertical direction in each of four rows arranged in the lateral direction. The four recessed sections 52 are provided at equal intervals in the lateral direction in each of four rows arranged in the vertical direction. Each recessed section 52 with a substantially L-shaped cross section is in the exhaust gas flow direction to the downstream side (ie, in 7 the right side) recessed. Each recessed section 52 extends in the lateral direction of the vehicle body (the substantially horizontal direction). A connecting section 52 is formed between each pair of recessed sections 52 to be open adjacent to each other in the vertical direction. The exhaust gas flows in the exhaust gas flow direction from the region upstream of the distribution plate 5 through the connecting section 53 to the area downstream of the distribution plate 5 , Because every recessed section 52 from the surface 50 the distribution plate 5 is recessed to the downstream side in the exhaust gas flow direction, the recessed portion works 52 as a rib, the rigidity of the distribution plate 5 elevated.

Because the distribution plate 5 to the downstream side in the exhaust gas flow direction, each recessed portion has 52 a vertical surface 52a which extends substantially in the vertical direction and a bottom surface 52b which extends substantially in the horizontal direction. Thus, each recessed section 52 designed so that the aqueous urea solution along the surface 50 the distribution plate 5 from above the recessed section 52 drips, evenly through the bottom surface 52b is received, which extends in the substantially horizontal direction.

Thus, in the sixth embodiment described above, the distribution plate 5 inclined to extend in the direction substantially perpendicular to the direction in which the aqueous urea solution from the injection port 31 is injected from. In addition, the recessed sections 52 on the surface 50 the distribution plate 5 educated. Each recessed section 52 is recessed toward the downstream side in the exhaust gas flow direction and extends in the side direction. In addition, the connection section 53 formed between each pair of recessed sections 52 to be open adjacent to each other in the vertical direction. Accordingly, the aqueous urea solution bounces off the surface 50 the distribution plate 5 in the direction that is substantially perpendicular to the surface 50 lies. A great deal of energy is due to the collision between the aqueous urea solution and the distribution plate 5 applied to the aqueous urea solution. Thus, the aqueous urea solution is atomized into finer components using the large impact energy. Accordingly, the atomized aqueous urea solution becomes the downstream side in the exhaust gas flow direction through the corresponding connection portion 53 passed through the flow of the exhaust gas. Thus, it is possible to improve the distribution efficiency of the atomized aqueous urea solution.

If any part of the aqueous urea solution, which is to the surface 50 the distribution plate 5 was injected on the surface 50 the distribution plate 5 and at a time of collision between the aqueous urea solution and the distribution plate 5 Forms the liquid film, and the aqueous urea solution that forms the liquid film, because of the weight of the aqueous urea solution along the surface 50 dripping down, the aqueous urea solution will pass through the bottom surface 52a each recessed section 52 added. Accordingly, the aqueous urea solution passing through each recessed section 52 is absorbed, heated by the exhaust gas and is evaporated. Thus it is possible Lich, to prevent the aqueous urea solution from the distribution plate 5 to the wall surface of the exhaust gas passage 1 falls down, and adhering the aqueous urea solution at the lower portion of the exhaust passage 1 effectively suppress.

Next, a seventh embodiment of the invention will be described with reference to FIG 9 to 11 described.

In The seventh embodiment is the arrangement of the distribution plate changed. The sections of the arrangement that are not the distribution plate in the seventh embodiment, they are the same like that in the first embodiment. That's why these and those of the first embodiment corresponding Sections by the same reference numerals, and their detailed description is omitted.

How out 9 and 10 Namely, in the seventh embodiment, a distribution plate extends 6 (the additive distribution plate) in the direction crossing the direction in which the exhaust passage passes 1 extends. Even more accurate is the distribution plate 6 in the substantially vertical direction. Also is the distribution plate 6 in the vertical direction to a center portion of the distribution plate 6 that is near a center of the exhaust passage 1 is arranged, inclined in a manner such that the central portion of the distribution plate 6 in the vertical direction in the exhaust gas flow direction downstream of end portions of the distribution plate 6 is positioned in the vertical direction. Thus, the distribution plate 6 a substantially V-shaped cross section. If the distribution plate 6 from the upstream side in the exhaust gas flow direction is the distribution plate 6 essentially rectangular. The distribution plate 6 is with the wall surface of the exhaust gas passage 1 using flange sections 61 connected by corners of the distribution panel 6 projecting outward in the radial direction.

How out 10 and 11 is also apparent, is a single recessed portion 62 on a surface 60 (that is, a surface on the upstream side in the exhaust gas flow direction) of the distribution plate 6 educated. The recessed section 62 is recessed to the downstream side in the exhaust gas flow direction (that is, in FIG 11 the right side). The recessed section 62 extends in the lateral direction from one end portion to the other end portion of the distribution plate 6 in the lateral direction, in a middle portion of the distribution plate 6 in the vertical direction, near the center of the exhaust passage 1 is arranged. plump pieces 63 and connecting sections 64 are on the surface 60 the distribution plate 6 provided. The baffle pieces 63 work as baffle sections. Every baffle piece 63 extends in the direction substantially perpendicular to the direction in which the aqueous urea solution from the injection port 31 the injector 3 out into the exhaust passage 1 is injected. The exhaust gas flows in the exhaust gas flow direction from the region upstream of the distribution plate 6 through the connecting sections 64 to the area downstream of the distribution plate 6 , Even more accurate is every baffle piece 63 around a lower edge of the corresponding connection opening 64 to the lower side in the exhaust gas flow direction inclined in such a way that the impact piece 63 extends in the direction substantially perpendicular to the direction in which the aqueous urea solution is injected. There are also straightening plates 65 at upper edges of the respective connecting sections 64 provided. Each straightening plate 65 is around the top edge of the corresponding connection section 64 inclined to the downstream side in the exhaust gas flow direction. After the aqueous urea solution with each baffle piece 63 collided and atomized, the atomized, aqueous urea solution is uniformly along the flow of the exhaust gas through the corresponding straightening plate 65 to the exhaust gas purification device 2 guided. Each of the construction pieces 63 and each of the straightening plates 65 By cutting and bending a section of the distribution plate 6 educated. Each connection section 64 is formed by forming the corresponding baffle piece 63 and the corresponding straightening plate 65 by cutting and bending portions of the distribution plate 6 to be open. Because every recessed section 62 from the surface 60 the distribution plate 6 is recessed to the downstream side in the exhaust gas flow direction, the recessed portion works 62 as a rib, the rigidity of the distribution plate 6 elevated. An impact piece 63 , a connecting section 64 and a straightening plate 65 determine a sentence. The two sets are regularly arranged in the vertical direction in each of rows arranged in the lateral direction, and the four sets are arranged regularly in the lateral direction in each of rows arranged in the vertical direction, each in one Area above the recessed section 62 and in an area below the recessed portion 62 , Ends of the recessed section 62 in the lateral direction are outward (to the exhaust passage 1 towards) ends of the distribution plate 6 open in the lateral direction.

Because the distribution plate 6 in this case has a substantially V-shaped cross-section in a manner such that the central portion of the vertices development board 6 in the vertical direction downstream of the end portions of the distribution plate 6 is positioned in the vertical direction in the exhaust gas flow direction, the exhaust gas flows in the exhaust passage 1 along the surface 60 the distribution plate 6 from the ends of the distribution plate 6 in the vertical direction to the central portion of the distribution plate 6 in the vertical direction because of the impact between the exhaust gas and the distribution plate 6 ,

Thus, in the seventh embodiment, energy is applied to the aqueous urea solution when the aqueous urea solution is added to each baffle 63 is injected with the baffle piece 63 clashes. The aqueous urea solution is atomized into fine components using the impact energy. Accordingly, the atomized aqueous urea solution becomes through the flow of the exhaust gas through the corresponding connection portion 63 above each baffle piece 63 led to the downstream in the exhaust gas flow direction side. Thus, it is possible to increase the efficiency of distribution of the atomized aqueous urea solution.

When the aqueous urea solution to the surface 60 the distribution plate 6 is injected, the aqueous urea solution adheres to the surface 60 the distribution plate 6 and forms a liquid film. The aqueous urea solution, which is at the surface 60 adheres, and the liquid film forms, is along the flow of the exhaust gas, which is along the surface 60 the distribution plate 6 from the ends of the distribution plate 6 in the vertical direction to the central portion of the distribution plate 6 flows in the vertical direction, to the recessed portion 62 guided. As a result, the aqueous urea solution through the recessed portion 62 added. Because of this, the aqueous urea solution passing through the recessed section 62 is received, effectively heated by the exhaust gas, whose temperature at a position near the center of the exhaust gas passage 1 is highest, and thus the aqueous urea solution is evaporated. In addition, the vaporized aqueous urea solution from the ends of the recessed portion 62 in the side direction is actively guided along the flow to the downstream side of the exhaust gas in the exhaust gas flow direction. Thus, it is possible to reliably prevent the aqueous urea solution from becoming the wall surface of the exhaust gas passage 1 dripping, and adhering the aqueous urea solution to the lower portion of the exhaust passage 1 effectively suppress.

Next, referring to 12 and 13 An eighth embodiment of the invention is described.

In The eighth embodiment is the arrangement of the distribution plate changed. The sections of the arrangement that are not the distribution plate in the eighth embodiment, are the same as those in the seventh embodiment. That's why they are and those of the seventh embodiment, corresponding portions denoted by the same reference numerals, and their detailed Description is omitted.

How out 12 is apparent, namely, in the eighth embodiment, a vertical portion 60a which extends in the vertical direction, between each pair of connecting portions 64 adjacent to each other in the lateral direction at the surface 60 the distribution plate 6 provided. A vertically recessed section 66 that extends in the vertical direction is in each vertical section 60a educated. How out 13 is visible, is each vertically recessed section 66 to the downstream side in the exhaust gas flow direction (that is, in FIG 13 the right side) recessed. A center portion of each vertically recessed portion 66 in the vertical direction is with the recessed section 62 connected. The depth of each vertical recessed section 66 Gradually rises from end portions of the vertically recessed portion 66 in the vertical direction to the central portion of the vertically recessed portion 66 in the vertical direction. The central portion of the vertically recessed portion 66 in the vertical direction, which has the greatest depth, is with the recessed portion 62 connected. The depth of the central portion of the vertically recessed portion 66 in the vertical direction is substantially the same as the depth of the recessed portion 62 ,

Accordingly, in the eighth embodiment, the aqueous urea solution adhering to the surface becomes 60 the distribution plate 6 adheres, and which forms a liquid film when the aqueous urea solution to the surface 60 and every baffle piece 63 the distribution plate 6 is injected from each vertically recessed section 66 along the flow of exhaust gas that flows along the surface 60 the distribution plate 6 flows from the ends of the distribution plate 6 in the vertical direction to the central portion of the distribution plate 6 in the vertical direction to the recessed portion 62 guided. Thus, the aqueous urea solution flows from the vertically recessed portions 66 active in the recessed section 62 and the aqueous urea solution passes through the recessed section 62 added. Because of this, the aqueous urea solution passing through the recessed section 62 is heated by the exhaust gas whose temperature is highest at a position near the center of the exhaust pipe, effectively, and the aqueous Urea solution is effectively evaporated. In addition, the vaporized aqueous urea solution from the ends of the recessed portion 62 is actively guided in the side direction along the flow of the exhaust gas to the downstream side in the exhaust gas flow direction. Thus, it is possible to prevent the aqueous urea solution from becoming the wall surface of the exhaust gas passage 1 dripping, and adhering the aqueous urea solution to the lower portion of the exhaust passage 1 effectively suppress.

The invention is not limited to the embodiments described above. The invention may be embodied in various modified examples without departing from the spirit and scope of the invention. For example, in each of the embodiments described above, the urea aqueous solution bounces from the injection port 31 the injector 3 is injected into the exhaust gas, with the distribution plate 4 . 5 or 6 at a position upstream of the exhaust gas purification device 2 including the catalyst 21 for selective reduction together. However, an exhaust gas purifying apparatus including a zeolite catalyst may be provided in the exhaust passage, and the fuel component (HC component) injected into the exhaust gas from the injection port of the injector may collide with the distribution plate at a position upstream of the exhaust gas purifying device.

In the fifth embodiment described above, the slots are 49a that extend in the lateral direction, in each baffle piece 49 formed at three positions in the vertical direction. However, the slot (s) may be formed in at least a portion that is not the baffle, for example, in the vertical portion.

Also, in the above-described seventh and eighth embodiments, the ends of the recessed portion are 62 in the lateral direction at the ends of the distribution plate 6 open to the outside in the lateral direction. However, the ends of the recessed portion in the side direction may not be open at the ends of the distribution plate in the side direction, and the recessed portion may extend from one end portion of the distribution plate in the side direction to the other end portion.

Also, in the above-described seventh and eighth embodiments, the distribution plate is 6 to the central portion of the distribution plate 6 which is at the middle of the exhaust passage 1 is arranged, in the vertical direction inclined in a manner that the central portion of the distribution plate 6 in the vertical direction downstream of end portions of the distribution plate 6 is positioned in the vertical direction in the exhaust gas flow direction. Thus, the distribution plate 6 a substantially V-shaped cross section. However, the distribution plate may be toward the center portion of the distribution plate that is near the center of the exhaust passage 1 is positioned to be spherically curved in a manner such that the center portion of the distribution plate is positioned downstream of an edge portion of the distribution plate, and thus the distribution plate may have a substantially curved bowl-shaped cross section.

Furthermore is in each of the embodiments described above the additive distribution plate at an exhaust passage for a diesel engine applied. However, the additive distribution plate can at an exhaust gas passage for a gasoline engine with direct injection be applied, depending on the NOx together with the exhaust gas can be delivered from an operating condition.

A distribution plate ( 4 ) disperses an aqueous urea solution injected into an exhaust passage for an engine at a position upstream of an exhaust gas purification device. The distribution plate ( 4 ) is arranged to extend in a direction crossing a direction in which the exhaust passage extends. Saved sections ( 42 ) which are recessed toward a downstream side in an exhaust gas flow direction are at a surface ( 40 ) of the distribution plate ( 4 ) intended. Impact pieces ( 43 ) are above the corresponding recessed portions ( 42 ) provided. Each baffle piece ( 43 ) is inclined to extend in a direction substantially perpendicular to a direction in which the aqueous urea solution is injected. Connecting sections ( 44 ) are above the corresponding impact pieces ( 43 ) provided. Exhaust gas flows from an area upstream of the distribution plate (FIG. 4 ) to an area downstream of the distribution plate ( 4 ) through the connecting sections ( 44 ).

QUOTES INCLUDE IN THE DESCRIPTION

This list The documents listed by the applicant have been automated generated and is solely for better information recorded by the reader. The list is not part of the German Patent or utility model application. The DPMA takes over no liability for any errors or omissions.

Cited patent literature

• - JP 2007-77957 [0005]

Claims (12)

Admixture distribution plate, which is an additive distributed at a position upstream of an exhaust gas purification device, which is provided in the exhaust passage, in an exhaust passage was injected for a machine characterized by comprising: a movement restriction section, at a surface of the additive distribution plate is formed, and the movement of the additive to the Limited surface of the additive distribution plate, wherein the additive distribution plate is arranged to be extends in a direction crossing a direction in which the exhaust passage extends so that the additive, the is injected into the exhaust passage, with a surface the additive distribution plate collides. An additive distribution plate according to claim 1, wherein: of the Movement restriction section, a recessed section is in an exhaust gas flow direction in which the exhaust gas flows, recessed to a downstream side is; and the recessed portion is in a lateral direction extends in the additive distribution plate. Adjunct distribution plate according to claim 1 or 2, also with: a baffle section above the movement restriction section is provided, and that is inclined to extend in one direction, essentially is perpendicular to a direction in which the additive in the exhaust passage is injected; and a connecting section, which is provided above the baffle section, and by the the exhaust gas in the exhaust gas flow direction from an upstream region the additive distribution plate to an area downstream the additive distribution plate flows. Adjunct distribution plate according to one of the claims 1 to 3, wherein the movement restricting portion is from one end portion to the other end portion of the additive distribution plate extends in the lateral direction. An additive distribution plate according to claim 4, wherein the movement restriction section in a manner to a Middle section of the movement restriction section in FIG the side direction is inclined, that the central portion of the movement restricting portion in the lateral direction below the end portions of the movement restricting portion is positioned in the lateral direction. Adjunct distribution plate according to claim 4 or 5, wherein ends of the movement restricting portion in FIG the lateral direction at ends of the additive distribution plate after are open on the outside. Adjunct distribution plate according to one of the claims 1 to 6, wherein the additive distribution plate to a central portion additive distribution plate near a center of the exhaust gas passage is arranged, inclined in a way that the middle section the additive distribution plate at one in the exhaust gas flow direction most downstream section in the additive distribution plate is arranged. Adjunct distribution plate according to one of the claims 1 to 6, wherein the additive distribution plate to a central portion the additive distribution plate in a vertical direction in is inclined in a way that the central portion of the additive distribution plate in the vertical direction in the exhaust gas flow direction downstream of end portions of the additive distribution plate is positioned in the vertical direction. An additive distribution plate according to claim 8, wherein the movement restricting portion at the central portion the additive distribution plate formed in the vertical direction is. Adjunct distribution plate according to one of the claims 1 to 6, wherein the additive distribution plate in a substantially vertical direction stands. Adjunct distribution plate according to one of the claims 1 to 6, wherein the additive distribution plate in the exhaust gas flow direction inclined backwards in a way that an upper end portion of the additive distribution plate downstream a lower end portion of the additive distribution plate positioned is. An additive distribution plate according to claim 3, wherein the baffle section has a plurality of slots.