SE1051091A1 - Arrangement and method for introducing a liquid reducing agent into exhaust gases from an internal combustion engine - Google Patents

Abstract

SUMMARY Arrangement and method for introducing a liquid reducing agent, for example urea, into exhaust gases from an internal combustion engine, wherein the reducing agent is injected by means of an injector (5) as a spray into a mixing channel (2) or exhaust gases. which is led into a mixing channel. The reducing agent is applied to an electric charge of a first polarity so that at least part of the droplets of reducing agent contained in the spray generated by the injector are caused to show an electric charge of this first polarity. One or more surfaces (11) of the mixing channel are applied to an electric charge of said first polarity so that the electrically charged reducing agent droplets are repelled by these surfaces, and / or one or more surfaces (8) of the mixing channel and / or of an arrangement arranged in the mixing channel. evaporator means (6) is kept grounded or an electric charge of a polarity opposite to said first polarity is applied so that the electrically charged reducing agent droplets are attracted by these surfaces. (Fi9 1)

Description

10 15 20 25 30 35 When urea is used as a reducing agent, it is injected into the exhaust gas the conduit in the form of a liquid urea solution by means of a injection means. The injection means comprises a nozzle via which the urea solution under pressure is injected into the exhaust line in atomized form as a spray. During large parts of a diesel engine operating condition, the exhaust gases have a sufficiently high temperature to be able to evaporate the urea solution so that ammonia is formed. The however, it is difficult to avoid that part of the added urea solution comes into contact with and gets stuck on the inside of the exhaust line wall surface in an undiluted state. Then an internal combustion engine is operated in a uniform manner over a period of time, i.e. during a stationary one operating conditions, no appreciable variations occur in the gas flow and the urea solution injected into the exhaust gases will therefore to hit essentially the same area of the exhaust line throughout this time period. Under the influence of it relatively cool urea solution, the temperature can be lowered locally in this area. which in turn can lead to the formation of a film of urea solution which is then entrained by the exhaust gas flow. After this film has been moved a certain distance in the exhaust line more water in the urea solution to boil off under the action of the hot the exhaust gases. What remains is solid urea which is slowly evaporated by the heat in the exhaust line. If the supply of solid urea is greater than the evaporation The accumulation of solid urea in the exhaust line takes place. If If the layer of urea becomes thick enough, the urea and its solids will sharing products to react with each other to form primitive polymers on urea base, so-called urea lumps. Such urea lumps can eventually block an exhaust line.

Thus, it is desirable that the injected urea solution be dispersed well into the exhaust gases so that the urea solution is prevented from essentially the same area of the exhaust line. A good spread of the urea solution in the exhaust gases also facilitates evaporation of the urea solution.

To facilitate the evaporation of the injected urea solution an evaporator means may be provided in the exhaust line 10 15 20 25 30 35 current injection site. This evaporator can in its The simplest form is a metal plate which is heated by the exhaust and on which reducing agent droplets are intended to get stuck and evaporate. The evaporator may alternatively exhibit a plurality of parallel channels intended to flow through of exhaust gases, the reducing agent droplets accompanying the exhaust are intended to be attached to the gases heated by the exhaust gases. the squeegee walls and evaporate. The evaporator may comprise catalytic material to accelerate the evaporation of the reduction the means or lack such material. In order to facilitate evaporation the injection of the injected reducing agent may in some cases it may also be desirable to obtain an even distribution of the reduction the means over one or more wall surfaces in the exhaust line as with high reliability is kept warm enough under the action of the hot the exhaust gases.

OBJECT OF THE INVENTION The object of the present invention is to provide an arrangement gemang of the type described above that creates improved opportunities to ensure a good evaporation of the injected the reducing agent.

SUMMARY OF THE INVENTION According to the present invention, said object is achieved by means of an arrangement having the features defined in claim 1 and a method having the methods defined in claim 4 the features.

According to the invention, reducing agents are injected by means of a injection means as a spray in a mixing channel or in gases which are led into a mixing channel, the reducing agent an electric charge of a first polarity is applied so that at least stone part of the drops of reducing agent contained in it the spray generated by the injection means is brought to display an electric charge of this first polarity. In addition, applied 10 15 20 25 30 35 one or more surfaces of the mixing channel an electric charge of said first polarity so that the electrically charged reduction poles the average droplets are repelled by these surfaces, and / or one or more surfaces of the mixing channel or of one in the mixing channel arranged evaporator is kept grounded or an electric is applied charging a polarity opposite said first polarity so that they electrically charged reducing agent droplets are attracted to them the latter surfaces. This allows the drops of the injected the reducing agent is easily guided away from the surfaces of the mixing channel where there is a risk of a strong and evaporative adversely affecting the concentration of reducing agents or where there is a risk of unfavorably low temperatures for evaporation. raturations may occur. As an alternative to or in combination with this repelling of the reducing agent droplets, the the droplets are controlled by and electric attraction towards and spread over surfaces that are expected to hold one for evaporation suitably high temperature, such as certain surfaces of the mixing channel or the surfaces of an evaporator arranged in the mixing channel organ. The electrically charged reducing agent droplets are coming in addition to repelling each other, which contributes to a good spread of the reducing agent droplets in the mixing channel.

Other advantageous features of the arrangement and procedure according to the invention appears from the dependent claims and the following description.

BRIEF DESCRIPTION OF THE DRAWINGS The invention will be described in more detail below using exemplary embodiments, with reference to the accompanying drawings.

It appears in: Fig. 1 is a schematic principle sketch of an arrangement according to a first embodiment of the present invention, Fig. 2 is a schematic principle sketch of an arrangement according to a second embodiment of the invention, 10 15 20 25 30 35 Fig. 3 is a schematic principle sketch of an arrangement according to a third embodiment of the invention, and Fig. 4 is a schematic principle sketch of an arrangement according to a fourth embodiment of the invention.

DETAILED DESCRIPTION OF EMBODIMENTS OF THE INVENTION Figs. 1-4 illustrate an arrangement 1 according to three different embodiments. forms of the present invention for introducing a liquid reducing agents in exhaust gases from an internal combustion engine. Arrange- the manifold may, for example, be arranged in an exhaust line an SCR catalyst is introduced to introduce a liquid reducing agent. urea solution in the upstream exhaust line The SCR catalyst, or be arranged in an exhaust gas aftertreatment device for introducing a liquid reducing agent into the mold of urea solution upstream of an exhaust gas aftertreatment device incoming SCR catalyst.

The arrangement 1 comprises a mixing channel 2 which is intended to receive at its upstream end exhaust gases from a combustion engine and direct these exhaust gases in the direction of a gas aftertreatment unit in the form of an SCR catalyst. Among- the duct 2 is thus intended to be traversed by the looks. The mixing channel 2 is delimited in the radial direction by one tubular wall 3 of metal, for example stainless steel. Exhaust gases are led into the mixing channel 2 via an upstream mixing channel arranged exhaust duct 4.

The arrangement 1 further comprises an injection means 5 which is arranged to inject under pressure the liquid reducing agent the agent in finely divided form as a spray in the mixing channel 2. The injection means 5 may, for example, comprise an injection nozzle. The injector 5 is suitably arranged to inject the reducing agent into the center of the mixing channel. 10 15 20 25 30 35 current end in the direction of the downstream end of the mixing channel, as illustrated in Figs. 1-4.

The flow direction of the exhaust gases in the mixing channel 2 is marked with the arrow P1 in Figs. 1-4.

In the embodiments illustrated in Figs. 1 and 2, an evaporation means 6 arranged in the mixing channel 2 downstream of the injection This evaporator 6 is made of metal, for example stainless steel, and is provided with a plurality of mutually parallel flow channels 7. The exhaust gases are intended to pass through these flow channels 7 while reducing droplets that accompany the exhaust gases hit and get stuck on the surfaces 8 of the walls 9 of the evaporator 6 which are separates the flow channels 7 from each other. The reduction agents thus captured by the evaporator wall surfaces 8 evaporate under the action of the heat of the exhaust gases. Evaporative or 6 could alternatively also have a different design and for example comprising a metal plate arranged in the mixing box channel 2 to capture the reducing agent droplets provided the passing exhaust gases. The evaporator 6 may comprise catalytic material or lack such material.

The arrangement 1 comprises charge control means 10 which are arranged to apply to the reducing agent an electric charge of a first polarity so that at least a portion of the droplets of reduction agent contained in the one generated by the injection means 5 the spray will exhibit an electrical charge of this sta polarity. The charge control means 10 are further arranged: to apply one or more surfaces 11 of the mixing channel 2 a electric charge of said first polarity so that they electrically the charged reducing agent droplets are repelled by these surfaces 11, and or holding one or more surfaces 8, 12 of the mixing channel 2 and / or in the evaporator provided in the mixing channel the means 6 grounded or apply an electric charge to these surfaces 8, 12. of a polarity opposite to said first polarity so that they 10 15 20 25 30 35 electrically charged reducing agent droplets are attracted to them surfaces 8, 12.

To achieve the desired charge of the injected reducer the charge means, any charging technique known per se can be used. turned. A variety of charging methods that can be used for this purpose is well known to those skilled in the art and will therefore not be described in more detail here.

In the illustrated embodiments, the charge control means are 10 arranged to charge the reducing agent with negative charge.

To accomplish this, the charge control means 10 may be pelvis comprise an electrode 13 of suitable design arranged in in the vicinity of the injection means 5. By feeding with the high voltage hazardous current, the electrode 13 generates an electrode static field which causes an ionization of the passers-by the reducing agent droplets, whereby they become negatively charged dade.

The charge control means 10 could alternatively be arranged charged the reducing agent with negative or positive charge. by triboelectric charging. In this case, examples the injection means 5 comprise a suitable material which is the passing reducing agent when the reducing agent more contact with this material.

In the embodiments illustrated in Figs. 1 and 2, the charge the control means 10 arranged to charge the tubular wall 3 with a charge of the same polarity as the reduction the average droplets, ie negative charge in the current examples, so that the electrically charged reducing agent droplets are repelled by this wall 3. In the examples illustrated in Figs. 1 and 2 include the charge control means 10 an electric current source 14, for example in the form of a battery, and the wall 3 is connected via a line 15 to a negative pole of the current source 14 so that under the action of the power source is subjected to a negative charge. 10 15 20 25 30 35 In the embodiment illustrated in Fig. 1, the charge control the means 10 are further arranged to charge the evaporator 6 with charge of opposite polarity compared to the reducing agent droplet the pairs, ie positive charge in the current example, so that they electrically charged reducing agent droplets are attracted to wall surfaces of the evaporator 8. In this case, of course, the steaming means 6 be electrically isolated from the mixing duct wall 3. In the example illustrated in Fig. 1, the evaporator via the line 16 connected to a positive pole of the current the source 14 for applying a positive under the action of the current source charge.

In the embodiment illustrated in Fig. 2, the charge control the means 10 arranged to pour the evaporator 6 grounded so that the electrically charged reducing agent droplets are attracted to the wall surfaces of the evaporator 8. In this case, the charging the control means 10 a line 17 connecting the evaporator means 6 with electric ground. Also in this case the evaporator 6 be electrically isolated from the wall of the mixing channel 3.

In the embodiments illustrated in Figs. 3 and 4, the charge the control means 10 arranged to charge a first part 3a of the mixed tubular wall 3 of the duct with charge of the same polar rite as the reducing agent droplets, i.e. negative charge in the current examples, so that the electrically charged reducing agents the drops are repelled by this first wall part 3a. In those in Fig. 3 and 4 illustrated, the charge control means 10 comprises a electrical power source 14, for example in the form of a battery, and it the first wall part 3a is connected via a line 18 to a negative pole of the power source 14 so that under the action of the power source a negative charge.

In the embodiment illustrated in Fig. 3, the charge control the means 10 are further arranged to hold a second part 3b of the mixed the tubular wall 3 of the duct is grounded so that the electrically charged the reducing agent droplets are attracted to this other wall part 3b. In this case, the charge control means 10 comprises a 10 15 20 25 line 19 which connects the second wall part 3b to electrical soil. In this case, of course, the first wall part 3a must be electrically isolated from the second wall part 3b.

In the embodiment illustrated in Fig. 4, the charge control the means 10 arranged to charge a second part 3b of the mixing the tubular wall 3 of the channel with charging of opposite polarity compared to the reducing agent droplets, i.e. positive charge in it current example, so that the electrically charged reducing agents the drops are attracted by this second wall part 3b. Even in this In this case, the first wall part 3a must be electrically insulated from the second wall part 3b. In the example illustrated in Fig. 4 is the second wall part 3b via a line 20 connected to a positive pole of the power source 14 so that under the action of the power source ras a positive charge.

The arrangement according to the invention is particularly intended to be used turned in a heavy motor vehicle, such as a bus, a towing vehicle or a truck.

The invention is of course not in any way limited to those above described embodiments, without a variety of possibilities for specifications thereof should be apparent to one skilled in the art. without departing from the invention basic idea such as this is defined in the appended claims.

Claims (6)

10 PATENT REQUIREMENTS Arrangement for introducing a liquid reducing agent, 10 15 20 25 30 35 Arrangement according to claim 1, for example urea, in exhaust gases from an internal combustion engine, which arrangement (1) comprises: - a mixing channel (2) intended to be passed through by exhaust gases, - an injector (5) for injecting the reducing agent as a spray in the mixing duct (2) or in exhaust gases introduced into the mixing duct (2), characterized in that the arrangement (1) further comprises charge control means (10) which are arranged: - to apply to the reducing means an electric charge of a first polarity so that at least one part of the droplets of reducing agent contained in the spray generated by the injection means (5) will have an electric charge of this first polarity, and - applying to one or more surfaces (11) of the mixing channel (2) an electric charging said first polarity so that the electrically charged reducing agent droplets are repelled by these surfaces (11), and / or holding one or more surfaces (8, 12) of the mixing channel (2) and / or of a evaporation means (6) arranged on the mixing channel, ground or apply to the latter surfaces (8, 12) an electric charge of a polarity opposite to said first polarity so that the electrically charged reducing agent droplets are attracted by these surfaces (8, 12). characterized in that the mixing channel (2) is delimited in the radial direction of a tubular wall (3), said charging means (10) being arranged to apply at least a part of this tubular wall (3) an electric charge of said first polarity so that the electrically charged reducing agent droplets are repelled by this part of the tubular wall. . Arrangement according to claim 2, characterized in that said charging means (10) are arranged: applying a first part (3a) of the tubular wall (3) to an electric charge of said first polarity so that the the electrically charged reducing agent droplets are repelled by this first part (3a) of the tubular wall, and - to keep a second part (3b) of the tubular wall (3) grounded, or to apply this second part (3b) of the tubular wall the wall an electric charge of a polarity opposite to said first polarity, so that the electrically charged reducing agent droplets are attracted by this second part (3b) of the tubular wall. . A process for introducing a liquid reducing agent, for example urea, into exhaust gases from an internal combustion engine, the reducing agent being injected by means of an injector (5) as a spray into a mixing channel (2) or into exhaust gases which are led into a mixing channel (2). ), characterized in that: - the reducing agent is applied to an electric charge of a first polarity so that at least a part of the drops of reducing agent contained in the spray generated by the injection means (5) is caused to show an electric charge of this first polarity, and - that one or more surfaces (11) of the mixing channel (2) are applied to an electric charge of said first polarity so that the electrically charged reducing agent droplets are repelled by these surfaces (11), and / or one or more surfaces (8, 12 ) of the mixing channel (2) and / or of an evaporator (6) arranged in the mixing channel is kept grounded or an electric charge of a polarity opposite to said first polar is applied so that the electrically charged reducing agent droplets are attracted to these surfaces (8, 12). . Method according to claim 4, wherein the mixing channel (2) is delimited in the radial direction of a tubular wall (3), characterized in that at least a part of the tubular wall (3) is applied to an electric charge of said first polarity so that the electrically charged reducing agent droplets are repelled by this part of the tubular wall. 10 12 Method according to claim 5, characterized in that: - a first part (3a) of the tubular wall (3) is applied to an electric charge of said first polarity so that the electrically charged reducing agent droplets are repelled by this first part (3a) of the tubular wall, and - that a second part (3b) of the tubular wall (3) is poured grounded, or an electric charge of a polarity opposite to said first polarity is applied, so that the electrically charged reducing agent droplets are attracted by this second part (3b) of the tubular wall.