DE102019210897A1 - Exhaust aftertreatment system for an internal combustion engine - Google Patents

Abstract

The invention relates to an exhaust gas aftertreatment system (2) for internal combustion engines, with at least one element (1) guiding and / or receiving a liquid exhaust gas aftertreatment agent, and with at least one protective agent which is designed to prevent the exhaust gas aftertreatment agent from freezing in a targeted manner in a limited freeze start area (6). to start on or in the element (1). It is provided that the protective agent in the freeze start area (6) has at least one crystallization nucleus that acts on the molecular level.

Description

The invention relates to an exhaust aftertreatment system for internal combustion engines, with at least one element guiding and / or receiving a liquid exhaust aftertreatment agent, and with at least one protective agent which is designed to allow the exhaust aftertreatment agent to begin freezing in a limited freeze start area on the element.

State of the art

From the publication DE 10 2012 223 028 A1 For example, an exhaust gas aftertreatment system for internal combustion engines is known which uses a usually liquid exhaust gas aftertreatment agent to reduce emissions in the exhaust gas. Frequently, an aqueous urea solution is used as the exhaust gas aftertreatment agent, which reacts with the exhaust gas from the internal combustion engine in a catalytic converter to reduce emissions. Because the exhaust gas aftertreatment agent freezes at temperatures below the freezing point and thereby increases its volume, it must be ensured that this increase in volume can be absorbed by the elements carrying or receiving the exhaust gas aftertreatment agent. Antifreeze protection is necessary which allows the exhaust gas aftertreatment agent to expand without damaging the exhaust gas aftertreatment agent. For this function to be effective, however, it must be ensured that the area of the element which takes up the additional volume, which is often characterized by elasticity or flexibility, does not freeze until the end of the freezing process or as the last area of the element. From the publication DE 10 2015 212 579 A1 it is known, for example, to specifically provide a freeze start area on or in the element as a protective means. For this purpose, the heat conduction of the exhaust gas aftertreatment agent into the environment at different points of the element is designed differently in the cited publication, so that if the ambient temperature drops in a defined freezing start area, the temperature of the exhaust gas aftertreatment agent is initially below the freezing temperature, while in other areas of the element it is not yet below the freezing temperature is.

Disclosure of the invention

The exhaust gas aftertreatment system according to the invention has the advantage that an improved start condition for the freezing of the exhaust gas aftertreatment agent is offered in or on the element, which can be implemented cost-effectively and in a space-saving manner without adversely affecting the other properties of the element. According to the invention, it is provided for this purpose that the protective means has at least one crystallization nucleus acting on the molecular level on a surface of the element facing the exhaust gas medium in the freeze start area. The crystallization process takes place on a molecular level. Molecules fit into a defined, solid lattice. Because the crystallization nucleus acts on a molecular level in the freezing start area, it is structure-forming for the lattice of the exhaust gas aftertreatment agent that is created during freezing. It causes an increase in the concentration of the crystallizing species. The bonds between the molecules arranged in the lattice thus remain stable, even if the formation of these bonds releases heat of fusion. The inventive design of the exhaust gas aftertreatment system therefore ensures that the exhaust gas aftertreatment agent freezes first at the desired point in the freeze start area.

According to a preferred development of the invention, a multiplicity of crystal nuclei are present in the freeze start area. As the number of crystallization nuclei increases, the probability that the exhaust gas aftertreatment agent will begin to freeze in the freeze start area increases.

It is particularly preferred that the surface of the element assigned to the medium is provided with an inert surface structure in areas outside the freeze start area. The inert structure ensures that freezing of the exhaust gas aftertreatment agent on the element is delayed in the areas outside the freeze start area, so that the probability that the exhaust gas aftertreatment agent will freeze first in the freeze start area is further increased.

The crystallization nucleus is preferably formed by an aluminum oxide coating or a hydrogen bridge-forming coating. These coatings lead to polar interactions with the exhaust gas aftertreatment agent, in particular if it contains urea, and thus ensure early freezing of the exhaust gas aftertreatment agent in the area of the freeze start area.

Furthermore, it is preferably provided that the crystallization nucleus is formed by a hydroxide or an acid group and / or by zeolites, in particular with acidic centers. These enable a strong interaction with the dissolved urea of the exhaust gas aftertreatment agent and thereby cause a concentration directly on the surface of the element, which facilitates the formation of a freezing germ in the exhaust gas aftertreatment agent.

According to a preferred development of the invention, the crystallization nucleus is formed by a surface or surface coating with partial structural elements of urea. This gives the surface coating an organic content. The use of urea or a coating that has structural elements of urea, such as the element R1NR2-CO-NH2, improves the formation of the freezing nucleus.

Furthermore, it is preferably provided that the inert surface is formed by a gold coating or a silicon-based glass coating, in particular on stainless steel. According to this embodiment, the element is thus preferably made of stainless steel, at least in the area of the surface interacting with the exhaust gas aftertreatment agent, and has a gold coating or silicon-based glass coating there. These coatings advantageously retard the freezing of the exhaust aftertreatment agent on the element.

The element is preferably designed as a tank container for a tank device. In particular, the tank container is designed as an exhaust gas aftertreatment agent tank.

According to a preferred embodiment of the invention, the element is designed as a guide element, in particular as a pipeline, and thus serves to guide and guide the exhaust gas aftertreatment agent.

Another embodiment of the invention provides that the element preferably forms or co-forms an injector, a pump or an actuatable valve. In particular, the element forms an element of an injector, a pump or an actuatable valve that conducts a hydraulic medium or a liquid medium.

• Figur ein Element eines Abgasnachbehandlungssystems in einer vereinfachten Schnittdarstellung.

The exhaust gas aftertreatment means particularly preferably has a plurality of identical or different elements which are designed as described above. The invention will be explained in more detail below with reference to the drawing. This shows the only one

• FIG. 1 shows an element of an exhaust gas aftertreatment system in a simplified sectional illustration.

The single figure shows an advantageous element in a longitudinal section 1 an exhaust aftertreatment system 2 for a motor vehicle not shown here. The element 1 is designed according to the present embodiment for guiding or guiding a liquid exhaust gas aftertreatment agent that has an aqueous urea solution. This is the element 1 in the present embodiment as a pipe element 3 manufactured. The element 1 has for this purpose an annular, for example circular, jacket wall 4th on that an interior 5 forms for performing the exhaust gas aftertreatment agent. The surface facing the interior 4th of the element 1 has a freeze start area 6 on which is limited, leaving another area of the surface 4th away from the freeze start area 6 differs and in particular an inert surface 7th having. The freeze start area 6 is characterized by the fact that it has a large number of crystallization nuclei acting at the molecular level.

This is what the element 1 in the freeze start area 6 for example an aluminum oxide coating or a hydrogen bridge-forming coating. This ensures that in the freezing start area there is an interaction with the urea dissolved in the exhaust gas aftertreatment agent, which accelerates the freezing of the exhaust gas aftertreatment agent. Hydroxide or acid groups, for example, can be present as the hydrogen bridge-forming surface. Zeolites with acidic centers, which are present on the surface facing the exhaust gas aftertreatment agent, also enable a strong interaction with the dissolved urea and thereby cause a concentration directly on the surface, which facilitates the formation of freezing nuclei.

It is also conceivable, but not shown in the figure, to provide the surface with an organic coating in the limited freeze start area, which already has partial structural elements of urea, such as the element R1NR2-CO-NH2, where R1 is an organic residue, such as for example a resin, an NR2, a hydrogen atom or another organic radical such as a CH3 group.

In the remaining contact area to the exhaust gas aftertreatment agent, the element 1 as an inert surface structure 7th preferably a gold-coated surface or a particularly functionalized, silicon-based glass coating on stainless steel, through which the freezing of the exhaust gas aftertreatment agent on the element 1 is delayed.

By being in the freeze start area 6 the freezing is accelerated and delayed in the remaining area, the result is that the freezing of the exhaust gas aftertreatment agent when the temperature drops below the freezing temperature begins specifically in the freezing start area and moves in a desired direction, as in the figure by an arrow 8th shown continues. This will ensure that there is a freezing order in the Exhaust aftertreatment system is guaranteed, through which in particular the freezing resistance of the overall system is guaranteed in an advantageous manner. According to a further embodiment, as an element 1 an element for keeping and storing the exhaust gas aftertreatment agent, such as a tank container, is present. The exhaust aftertreatment system 2 in particular has several elements 1 that are formed the same or different, with one or more of the elements 1 the described freeze start range 6 and at least one or more of the elements 1 the described freeze delay range with an inert surface 7th exhibit. It can also be provided that the element is designed as a component of an injector, a pump or an actuatable valve or switching valve of a hydraulic system. For example, it is designed as a component of an injector for dosing an exhaust gas aftertreatment agent into the exhaust system of an internal combustion engine, or as a pipe that leads to the injector, or as a component of a pump that delivers the exhaust gas aftertreatment agent to the injector, for example through the pipe.

QUOTES INCLUDED IN THE DESCRIPTION

This list of the documents listed by the applicant was generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Patent literature cited

• DE 102012223028 A1 [0002]
• DE 102015212579 A1 [0002]

Claims (10)

Exhaust aftertreatment system (2) for internal combustion engines, with at least one element (1) guiding and / or receiving a liquid exhaust aftertreatment agent, and with at least one protective agent that is designed to freeze the exhaust aftertreatment agent in a targeted manner in a limited freeze start area (6) on or in the Let element (1) begin, characterized in that the protective agent in the freeze start area (6) has at least one crystallization nucleus acting on the molecular level. Exhaust aftertreatment system Claim 1 , characterized in that a plurality of crystal nuclei are present in the freeze start area (6). Exhaust gas aftertreatment system according to one of the preceding claims, characterized in that the surface of the element (1) assigned to the medium is provided with an inert surface (7) in an area outside the freeze start area (6). Exhaust gas aftertreatment system according to one of the preceding claims, characterized in that the crystallization nucleus is formed by an aluminum oxide coating or a coating that forms hydrogen bridges. Exhaust gas aftertreatment system according to one of the preceding claims, characterized in that the at least one crystallization nucleus is formed by a hydroxide or acid group or by zeolites. Exhaust gas aftertreatment system according to one of the preceding claims, characterized in that the crystallization nucleus is formed by a surface or surface coating with partial structural elements of urea. Exhaust gas aftertreatment system according to one of the preceding claims, characterized in that the inert surface (7) is formed by a gold coating or a silicon-based glass coating. Exhaust gas aftertreatment system according to one of the preceding claims, characterized in that the element (1) is designed as a tank container. Exhaust gas aftertreatment system according to one of the preceding claims, characterized in that the element (1) is designed as a guide element, in particular as a pipe (3). Exhaust gas aftertreatment system according to one of the preceding claims, characterized in that the element (1) forms or forms an injector, a pump or an actuatable valve.

Images