EP1342950A2 - Atomizing nozzle for a burner - Google Patents

Abstract

The nozzle has a flow guide unit (16) providing a surface (28) and includes an atomizing lip in an end area (34). A feed device feeds fuel into the guide surface at a spaced location from the lip and includes a fuel release depression (50) into which a fuel feed channel device (52) is opened at a junction area.

Description

The present invention relates to an atomizer nozzle for a burner, in particular for a vehicle heating device, comprising a flow guide element providing a flow guide surface, which has an atomizer lip in one end region, and a fuel supply arrangement for supplying fuel to the flow guide surface at a distance from the atomizer lip.

From EP 0 910 776 B1 an atomizing nozzle is known of the kind used in combustion chambers of gas turbines used as aircraft engines. In this known atomizer nozzle, the air stream entering the gas turbine is divided. Part of the air supplied is introduced into an atomizing nozzle in the form of an outer swirl flow and an inner swirl flow. A flow guide element separates the outer swirl flow from the inner swirl flow and in particular also forms a flow guide surface for the inner swirl flow, which ends in an atomizer lip in an axial end region of the flow guide element. By means of an injection nozzle arranged centrally with respect to the flow guide element, the fuel is sprayed onto this flow guide surface through the inner swirl flow moving along the mentioned flow guide surface and then moves along this in the direction of the atomizer lip. If the fuel film formed for the inner swirl flow by spraying onto the mentioned flow guide surface reaches the atomizer lip, it is atomized by the shear flow present in the area of the atomizer lip. The atomized fuel flows together with the combustion air supplied by the outer swirl flow and the inner swirl flow into the combustion chamber, where it is also burned in combination with the air that is first directed past the atomizing nozzle.

Starting from such an atomizer nozzle, it is the object of the present invention to provide an atomizer nozzle for a burner, as can be used in particular in a vehicle heating device, which leads to improved combustion of the introduced fuel.

According to a first aspect of the present invention, this object is achieved by an atomizer nozzle for a burner, in particular for a vehicle heater, comprising a flow guide element providing a flow guide surface, which has an atomizer lip in one end region, and a fuel supply arrangement for supplying fuel to the flow guide surface at a distance from the atomizer lip.

According to the invention, it is further provided that the fuel supply arrangement in the flow guiding element comprises a fuel delivery depression, into which a fuel supply duct arrangement opens in a confluence area.

By supplying the fuel in the atomizer nozzle according to the invention directly to the flow guide surface while avoiding the passage of the supplied fuel through the air flowing along the flow guide surface, a significantly better quality of the fuel atomization is achieved, since it can be avoided that fuel particles pass through the atomizer nozzle Air is carried along without being conducted to the atomizer lip via the flow guide surface. A more even distribution of the fuel to be atomized can also be achieved in this way the flow guide surface in the area in front of the atomizer lip.

In order to make the distribution of the fuel to be atomized on the flow guidance surface even more uniform, it is proposed that at least one fuel distribution element is provided in the fuel delivery depression for conveying fuel fed into the fuel delivery depression via the fuel supply channel arrangement to areas of the fuel delivery depression which are further away from the confluence area. It can be provided here, for example, that the fuel distribution element is designed to convey the fuel using a capillary action.

A capillary flow can also be achieved using comparatively insensitive structures or materials, for example, in that the fuel distribution element, in cooperation with a surface area that limits the fuel delivery depression in the flow guiding element, delimits a capillary flow channel arrangement.

It is further proposed that the fuel distribution element has at least one fuel passage area to enable fuel to escape from the fuel delivery sink. The fuel distribution element may comprise at least one elongate element, for example made of wire material, which extends along the fuel delivery depression. In addition, in an advantageous further development, it is possible for the fuel distribution element to have a plurality of elongate elements which abut one another and form a capillary flow channel arrangement between them. The individual elongated elements to be considered as strands of, for example, a braid-like composite form, especially when they are formed with a circular cross section, necessarily very fine between them Channels through which the fuel can then be conveyed away from the confluence area.

Alternatively, it is also possible for the at least one fuel distribution element to be formed from porous material.

The confluence region preferably has at least one confluence point at which a fuel supply duct section of the fuel supply duct arrangement opens into the depression. In order to allow a certain pre-distribution to take place here, it is of course possible to provide several junction points distributed along the fuel delivery depression.

It is further proposed that the junction area be formed in a bottom area of the same, which radially delimits the fuel discharge depression. In order to give the fuel a certain flow component in the longitudinal direction of the fuel upon introduction into the fuel delivery depression and thus to further improve the distribution of the fuel over the length of the fuel delivery depression, it is proposed that the fuel supply duct arrangement have at least one fuel supply duct section that opens substantially tangentially into the ring-shaped or ring-segment-shaped fuel delivery depression section includes.

In an embodiment of the atomizing nozzle according to the invention that is particularly preferred for fluidic reasons, it can be provided that the flow guiding element is constructed essentially concentrically to a central axis and that the fuel delivery depression is designed as an annular groove-like depression arranged essentially concentrically with respect to the central axis.

In order to be able to atomize the fuel supplied via the atomizer nozzle according to the invention using shear flows, it is proposed that the flow guide element separate an outer swirl flow from an inner swirl flow and that the flow guide surface is a surface of the flow guide element which guides the inner swirl flow. It can be provided, for example, that the flow guide element is surrounded in an axial end region thereof that provides the atomizer lip by an outer flow guide element that guides the external swirl flow together with the flow guide element. Furthermore, for guiding the inner swirl flow, it is proposed that the flow guiding element surrounds an inner flow guiding element guiding the inner swirl flow at least in regions, and that the fuel release depression is at least partially formed in a region of the flow guiding element surrounding the inner flow guiding element.

In a further particularly advantageous embodiment of the atomizer nozzle according to the invention, it can be provided that the entire combustion air used to burn the fuel atomized by means of the atomizer nozzle is supplied by the outer swirl flow and the inner swirl flow. In this way it can be achieved that in the entire combustion chamber the combustion taking place in a burner having the atomizer nozzle according to the invention takes place with excess air, ie in a lean area. In addition to the fact that a very large amount of air can be used for atomization, a reduction of the NOx emission is achieved by passing all the combustion air through the atomizer nozzle. It should be pointed out here that in the sense of the present invention, of course, if a plurality of atomizer nozzles are to be provided in a burner, the outer and inner swirl flows of all atomizer nozzles generally as the outer swirl flow and the internal swirl flow is to be understood, which in turn means that all the air used for combustion is introduced into a burner via the various atomizing nozzles.

A further advantageous aspect of the atomizer nozzle according to the invention is that an ignition element is provided for igniting a combustion air / fuel mixture in a volume area which is at least partially delimited by the flow guidance element.

According to a further aspect of the present invention, the object mentioned at the outset is achieved by an atomizer nozzle for a burner, in particular for a vehicle heater, comprising a flow guide element which provides a flow guide surface and has an atomizer lip in an end region, the flow guide element having an outer swirl flow from an inner swirl flow separated, and a fuel supply arrangement for supplying fuel to the flow guide surface at a distance from the atomizer lip.

It is then provided according to the invention that all of the combustion air used to burn the fuel atomized by means of the atomizer nozzle is supplied by the outer swirl flow and the inner swirl flow.

As already explained, this arrangement leads on the one hand to the advantage of improved atomization, since a larger amount of air can be used than in the case in which only part of the air required for combustion flows through one or more atomizer nozzles. Furthermore, the improved mixing of the atomized fuel with the air supplied also improves combustion and thus low pollutant emissions.

According to a further aspect of the present invention, this provides an atomizer nozzle for a burner, in particular for a vehicle heater, comprising a flow guide element providing a flow guide surface, which has an atomizer lip in one end region, and a fuel supply arrangement for supplying fuel to the flow guide surface at a distance from the atomizer lip.

In this atomizer nozzle, an ignition element for igniting a combustion air / fuel mixture is then further provided in a volume area which is at least partially delimited by the flow guiding element.

This embodiment of an atomizer nozzle according to the invention leads to the advantage of an accelerated ignition process, with the result that pollutant emissions can be reduced, in particular during the ignition process. It can be provided here, for example, that the flow guiding element separates an outer swirl flow from an inner swirl flow and that the ignition element for igniting the combustion air / fuel mixture is effective in a return flow region formed centrally in the inner swirl flow.

Furthermore, the present invention relates to a vehicle heater which has a burner with an atomizing nozzle according to the invention, or a device for the thermal treatment of an exhaust gas aftertreatment system, in particular for the thermal regeneration of a particle filter and / or for heating a catalyst, which device has a burner equipped with an atomizing nozzle according to the invention has, which is preferably positioned or positionable in the exhaust gas flow. Furthermore, the present invention relates to a device for generating process gases from liquid fuels, such as gasoline, diesel, Heating oil, methanol, ethanol, which device has a burner equipped with an atomizing nozzle according to the invention.

Fig. 1

eine Teil-Längsschnittansicht einer erfindungsgemäßen Zerstäuberdüse;

Fig. 2

eine Seitenansicht eines bei der Zerstäuberdüse der Fig. 1 eingesetzten und als Innen-Strömungsführungslement wirksamen Bodenelements;

Fig. 3

eine perspektivische Ansicht eines Zentral-Strömungsführungselementes der in Fig. 1 dargestellten Zerstäuberdüse;

Fig. 4

eine Querschnittansicht des in Fig. 3 dargestellten Zentralströmungsführungselementes, geschnitten in einer Ebene IV - IV in Fig. 5;

Fig. 5

eine Längsschnittansicht des in Fig. 3 dargestellten Zentral-Strömungsführungselementes, geschnitten in einer Ebene V-V in Fig. 4;

Fig. 6

eine perspektivische Ansicht eines Außen-Strömungsführungselementes der in Fig. 1 dargestellten Zerstäuberdüse;

Fig. 7

eine Längsschnittansicht des in Fig. 6 dargestellten Außen-Strömungsführungselementes;

Fig. 8

eine Prinzip-Längsschnittansicht einer erfindungsgemäßen Zerstäuberdüse, welche insbesondere den Aufbau und die Wirksamkeit des Zentral-Strömungsführungselementes erkennen lässt;

Fig. 9

eine vergrößerte Ansicht des Details IX in Fig. 8;

Fig. 10

einen Teil des in Fig. 9 erkennbaren Brennstoffverteilungselementes;

Fig. 11

eine der Fig. 9 entsprechende Ansicht, welche eine alternative Ausgestaltungsart eines Brennstoffverteilungselements zeigt;

Fig. 12

eine weitere der Fig. 9 entsprechende Ansicht, welche eine alternative Ausgestaltungsart eines Brennstoffverteilungselements zeigt;

Fig. 13

eine weitere der Fig. 9 entsprechende Ansicht, welche eine alternative Ausgestaltungsartdes Zentral-Strömungsführungselements darstellt.

The present invention will be described below in detail with reference to the accompanying drawings. It shows:

Fig. 1

a partial longitudinal sectional view of an atomizer nozzle according to the invention;

Fig. 2

a side view of a bottom element used in the atomizer nozzle of FIG. 1 and effective as an internal flow guide element;

Fig. 3

a perspective view of a central flow guide element of the atomizer nozzle shown in Fig. 1;

Fig. 4

a cross-sectional view of the central flow guide element shown in Figure 3, cut in a plane IV - IV in Fig. 5.

Fig. 5

a longitudinal sectional view of the central flow guide element shown in Figure 3, cut in a plane VV in Fig. 4.

Fig. 6

a perspective view of an outer flow guide element of the atomizing nozzle shown in Fig. 1;

Fig. 7

a longitudinal sectional view of the outer flow guide element shown in Fig. 6;

Fig. 8

a principle longitudinal sectional view of an atomizer nozzle according to the invention, which in particular the structure and Effectiveness of the central flow guide element can be seen;

Fig. 9

an enlarged view of detail IX in Fig. 8;

Fig. 10

part of the fuel distribution element shown in FIG. 9;

Fig. 11

9 is a view corresponding to FIG. 9, which shows an alternative embodiment of a fuel distribution element;

Fig. 12

another view corresponding to FIG. 9, which shows an alternative embodiment of a fuel distribution element;

Fig. 13

another view corresponding to Fig. 9 showing an alternative embodiment of the central flow guiding element.

In Fig. 1, an atomizer nozzle 10 according to the invention is shown in partial longitudinal section. Such an atomizing nozzle 10 can, according to an advantageous aspect of the present invention, be used in a heating burner for a vehicle heating device, such as e.g. Auxiliary heating or auxiliary heater can be used. It is also possible to use an atomizer nozzle 10 of this type in a burner of the type used for the regeneration of particle filters in exhaust systems, for example exhaust systems.

The atomizer nozzle 10 according to the invention comprises, for example, a nozzle body 12 which is fixed or can be fixed on a burner wall. Essentially three insert parts 14, 16, 18 are arranged in this nozzle body 12, which are described in detail below. The insert parts 14, 16, 18 are in one Opening 20 of the nozzle body 12 arranged in such a way that in the radially outer region of the insert parts 14, 16, 18 to a wall 22 of the nozzle body 12 surrounding this, an intermediate space 24 for supplying combustion air is formed by means of a fan.

The insert part 14, which is also shown in its entirety in FIG. 2, forms a base element or an inner flow guide element which, together with the insert part 16 to be considered as a central flow guide element, delimits a flow space region 26 for an inner swirl flow described below. The insert part or inner flow guide part 14, as can be seen in FIG. 2, is constructed rotationally symmetrically to a longitudinal center axis A of the atomizing nozzle 10 and provides a rotationally symmetrical flow guide surface leading from radially outside to radially inside and, apart from a curvature of the same frustoconical flow guide surface 27. In a corresponding manner, the insert part or central flow guide element 16 axially adjoining the insert part 14 provides a flow guide surface 28 which is opposite the flow guide surface 27 of the inner flow guide element 14 and together with it delimits the flow space 26 for the inner swirl flow. In order to give the combustion air coming radially inward from the radially outer intermediate space 24 through the conveying action of the blower (not shown) into the flow space region 26, the central flow guide element 16 has on its side facing the flow guide surface 27 of the inner flow guide element 14 a plurality of flow deflection elements 32 in the form of a spiral section are provided. These lie on the flow guide surface 27 of the inner flow guide element 14 in order to avoid flow losses. The flow space region 26 for the internal swirl flow is thus divided into a plurality of flow sections which follow one another in the circumferential direction.

The central flow guide element 16 has, in an approximately cylindrical end region 34 which is at a distance from the inner flow guide element 14, an atomizer lip 36 which is ring-like due to the symmetry of the central flow guide element 16 with respect to the longitudinal center axis A. This means that the flow guide surface 28 of the central flow guide element 16, through which the inner swirl flow is limited radially outwards, also ends at this atomizer lip 36.

On its other axial or radial side, ie the side opposite the flow guide surface 28, the central flow guide element 16 forms a further flow guide surface 38 for an external swirl flow. A flow space area 40 for the external swirl flow is delimited between the flow guide surface 38 of the central flow guide element 16 and a flow guide surface 42 opposite this flow guide surface 38 of the insert part 18 to be regarded as the outer flow guide element. The outer flow guide element 18 shown in greater detail in FIGS. 6 and 7 has a plurality of flow deflecting elements 44 in the area of its flow guide surface 42, which are likewise designed in the manner of a spiral section and are arranged in succession in the circumferential direction. When assembled, these flow deflecting elements 44 abut on the flow guide surface 38 of the central flow guide element 16 on their side remote from the flow guide surface 42 and thus, in cooperation with the two flow guide surfaces 38, 42, delimit a plurality of sections of the flow space region 40 for the outside in the circumferential direction -Drallströmung. The outer flow guide element 18 forms an apex region 46 of the flow guide surface 42, in which it has the smallest diameter with respect to the longitudinal center axis A. This apex region 46 is located upstream of the atomizer lip 36. This apex region also adjoins 46 a diffuser area 48, which then widens in the flow direction.

The flow air which is supplied from the radially outside through the space region 24 and then divided into the two flow space regions 26, 40 under the action of the blower already mentioned flows in the form of the inner swirl flow S _i and the outer swirl flow S _a from the radially outside to the radially inside and thus arrives from both sides, ie from the outside and from the inside into the area of the atomizer lip 36. In this case, given in each case by the geometry of the flow deflecting elements 32, 44, these two swirl currents S _i and S _{a can} have the same direction of rotation or an opposite direction to one another Show sense of rotation. These two swirl currents S _i and S _a then meet in the area of the atomizer lip 36 and lead to the atomization of the fuel, which is also led to the atomizer lip 36, as described below primarily with reference to FIGS. 8 to 10.

It can be seen in FIG. 8 that an annular groove-like depression 50 is formed in the central flow guiding element 16 in the region of the flow guiding surface 28, which depression is designed to run around the longitudinal center axis A in the example shown. This depression or depression 50 providing a fuel delivery depression can be produced, for example, by machining, but can also be obtained by assembling the central flow guiding element 16 from two correspondingly shaped components which together form the depression 50. As can also be seen above all in FIG. 4, a fuel feed channel arrangement, generally designated 52, opens into this depression 50. In the example shown, this comprises a fuel feed channel section 54 which is essentially tangential with respect to the ring-shaped depression 50 and which opens into the bottom region 56 of the depression 50. In the depression 50 there is also a wire or other material ring 59 in the example shown trained fuel distribution element 58 is provided. This lies in those areas of the depression 50 into which no fuel supply channel section 54 opens, both on the bottom area 56 and on the two side walls 60, 62 which essentially delimit the depression 50 together with the bottom area 56. If necessary, small gaps can also be formed here. As already stated, the fuel distribution element 58 can be designed, for example, as an open wire ring 59 to enable insertion, the length dimensioning preferably being such that in the inserted state the two end regions are then flush with one another and possibly leaving only a small gap , As can be seen in FIGS. 9 and 10, the recesses 64 in the fuel distribution element 58 have several positions. As can be seen above all in FIG. 9, these cutouts 64 establish a connection to channel regions 66 at several circumferential positions, which are formed by the fuel distribution element 58 and the surfaces delimiting the depression 50, that is to say essentially the walls 60, 62 and the base region 56 , are limited.

As already mentioned above, the fuel is supplied via the at least one fuel supply channel section 54 of the fuel supply channel arrangement 52 into the area of the bottom area 56. The fuel may reach the channel areas 66 under pre-pressure, with appropriate dimensions, which also relate to the viscosity of the fuel used can be coordinated, the fuel located in the channel regions 66 is conveyed forward by capillary action, so that it also reaches, for example, the regions in which the cutouts 64 establish a connection to the radially inward side of the depression 50. At the recesses 66 which are then distributed over the circumference, the fuel conveyed to these areas by capillary action and possibly also by pre-pressure action then emerges from the depression 50 and, as can be seen in FIG. 8, forms under the action of the internal swirl flow S _i one the flow guiding surface 28 in the area between the depression 50 and the atomizer lip 36 wetting fuel film 68.

Due to the above-mentioned conveying effect, the fuel is distributed very evenly in the circumferential direction around the longitudinal central axis A in the depression 50, even when only a single fuel supply channel section 54 is provided, so that there is an equally uniform wetting of the flow guide surface 28 in the mentioned area thereof. The consequence of this is that a very uniform fuel atomization is also produced over the circumference of the atomizer lip 36 under the action of the two swirl flows S _i and S _a and the shear effect present in the area of the atomizer lip 36. The uniform fuel atomization results in an equally evenly distributed combustion of the fuel particle / combustion air mixture thus produced. This in turn results in very low-pollutant combustion, which can also be supported, in particular in accordance with a further aspect of the present invention, by supplying all the air required and used for the combustion of the fuel supplied in the form of the two swirl flows S _i and S _a . A very efficient shearing action and thus a very good premixing of the fuel particles generated by atomization with the supplied combustion air can be obtained even in the area near the atomizer nozzle. It should be pointed out here that, of course, in the case of a burner which has a plurality of atomizing nozzles 10 according to the invention, the total air used for combustion is then divided up among the various atomizing nozzles, the individual amounts of combustion air then supplied to the atomizing nozzles then completely in the form of the two swirl flows S _i and S _a are introduced into the combustion chamber via the atomizing nozzle 10.

Another advantage of the fuel supply according to the invention via the groove-like depression 50 is the avoidance of the need to supply the fuel Promote fuel through one of the swirl flows to a flow guide surface. Furthermore, the depression with the fuel distribution element 58 present therein forms a fuel reservoir, so that even in the event of pressure fluctuations or quantity fluctuations in the fuel supply, the fuel delivery can be made more uniform in the direction of the atomizer lip 36.

An alternative embodiment of a fuel distribution element 58 is shown in FIG. 11. Here, this comprises a plurality of strands 69, which are again made of wire material, for example, which are wound or possibly also braided around a core 70 in the manner of a rope. Between these strands 69 and possibly also to the core 70, channel areas 72 again arise, which now produce a capillary conveying effect in addition to the channel areas 66 already mentioned above. Here too, in principle, a fuel distribution element 58 is provided, which is elongated in the direction of the depression 50 encircling the longitudinal center axis A and in which, due to the twist or the mesh-like surface contour, the mentioned exit areas are then formed, via which the fuel introduced through the fuel supply channel section 54 after distribution can take advantage of the capillary conveying effect in the direction of flow guide surface 28.

It should be pointed out here that for the fuel distribution element 58 of FIG. 11 as well as the fuel distribution element shown in FIGS. 8 and 9, any suitable material, such as e.g. Metal material, fuel and heat resistant plastic material or ceramic material can be used.

FIG. 12 shows a further embodiment of a fuel distribution element 58, which is designed here as a porous body 72 inserted into the depression 50. In the area 56 facing the floor Section may be provided in the porous body 72 for a pre-pressure distribution of the fuel introduced through the fuel supply channel section 54. Here, a pre-distribution can take place in the bottom area 56, which can of course also be the case in the embodiment of FIG. 11. The delivery to the flow guide surface 28 then takes place, however, in order to equalize it using a capillary action.

A further embodiment of a fuel distribution element, not shown, can comprise, for example, a tube-like element which, in its tube wall, has a plurality of openings, which may be of comparatively small dimensions, through which fuel that is supplied and possibly already pre-distributed in the region of the bottom region 56 can enter, and on the other hand, in the section facing away from the bottom region 56, the fuel can then escape again in the direction of the flow guide surface 28.

It should be pointed out that, of course, the aforementioned depression 50 and also the various fuel distribution elements 58 that can be provided therein do not necessarily have to be circumferential in the circumferential direction about the longitudinal center axis A, although this is very advantageous due to production-related reasons and because the fuel delivery is as uniform as possible. The various fuel distribution elements 58 can also be composed of a plurality of segments which are arranged in succession in the circumferential direction, for example in the case of a depression 50 which is circumferential in the circumferential direction.

FIG. 13 shows a further embodiment of a central flow guide element 16 according to the invention, in which the fuel supply is likewise via a in the area of the flow guide surface 28 the same provided groove-like and preferably circumferential depression 50 takes place. Also preferably in this depression 50 in the bottom region 56 thereof a plurality of fuel feed channel sections 54 follow one another in the circumferential direction. The wall 62 delimiting the depression 50 downstream forms an edge which acts as a weir in the transition region 76 to the flow guidance surface 28 and which produces a metered delivery of fuel from the depression 50 to the region of the flow guidance surface 28 which then follows downstream. That is, even without inserting a fuel distribution element, as has been discussed above, in particular when a plurality of fuel supply channel sections 54 supplying fuel distributed in the circumferential direction are provided, a very uniform fuel delivery in the direction of the atomizer lip 36 can be achieved.

Another aspect of the present invention can be seen in FIG. One sees there in an area centered with respect to the longitudinal center axis A, an ignition element 80, for example designed as a glow plug. This is positioned such that its end area 82, which provides the temperatures required for ignition, is in a volume area delimited radially outwards by the central flow guide element 16 84 protrudes, in which a recirculation R generated due to the flow dynamics is also present. The combustion air, which is also guided centrally in this area with respect to the internal swirl flow S _i , already contains the finest fuel particles generated in the area of the atomizer lip 36, so that an inflammable fuel particle / combustion air mixture reaches the area of the ignition element 80 through this recirculation R. , In order to protect the glow ignition element 80 against excessive cooling due to the internal swirl flow S _i flowing in at a comparatively high speed, it is possible, for example, to place it in the central region of the inner flow guide element which can be seen in FIGS. 1 and 2 effective insert. Furthermore, especially in the end region 82, the ignition element 80 can be surrounded by a braid-like or porous shielding material with a small space being left between. In this intermediate space, fuel accumulation in the porous or mesh-like material then creates an atmosphere which is essentially shielded from air currents and which has very good properties for ignition.

The atomizer nozzle according to the invention leads to very uniform combustion when used in a burner of a heating device, such as a vehicle auxiliary heater. This is essentially due to the fact that there is a very uniform supply of fuel in the direction of the atomizer lip and that a very large amount of air, namely essentially all of the air used to burn the atomized fuel, is also used to generate the fine fuel particles. Nevertheless, the atomizing nozzle according to the invention can also be used in other areas of application, such as, for example, a regeneration burner for a particle filter in the exhaust system of an internal combustion engine, as disclosed, for example, in DE 195 04 183 A1. In particular also with regard to the construction of such a regeneration burner, the disclosure content of this published specification is included by reference to the disclosure content of the present text. Another area of application of an atomizer nozzle according to the invention or of a burner containing such an atomizer nozzle in an exhaust gas aftertreatment system is the preheating of a catalyst provided for exhaust gas purification. The burner, which then acts as a so-called cat burner and can also be positioned in the exhaust gas flow, serves to bring the catalytic converter to a suitable operating temperature as quickly as possible when a vehicle engine is started, in order to reduce pollutant emissions during the cold start phase. Another area in which the atomizing nozzle according to the invention or a burner containing it can be used is the generation of process gases, for example for fuel cells liquid fuels, such as gasoline, diesel, heating oil, methanol, ethanol etc. Here, using a cold flame, i.e. a flame with a comparatively low temperature, a process gas is used, for example, as an energy source for the vehicle drive, for generating electrical energy, for example for vehicle electrical systems, or provided for heat generation in a vehicle preheater. Process gas generated in this way can also be used in the household sector both for the production of electrical energy and for heating buildings.

It should be pointed out that, in particular, the group of features relating to the fuel supply via an annular groove can also be used in an atomizer nozzle in which only one of the swirl flows, that is to say for example the inner swirl flow, is present and then along the assigned flow guide surface and the one provided therein Sink flows and thereby takes the fuel supplied via this depression in the direction of the atomizer lip.

All of the air required or used for combustion can then be supplied in the context of this single flow, which of course could also be the external swirl flow. It is also pointed out that the fuel could also be supplied in the region of the flow guide surface 38 lying outwards and leading to the atomizer lip 36.

Claims (23)

Atomizer nozzle for a burner, in particular for a vehicle heater, comprising: a flow guide element (16) providing a flow guide surface (28), which has an atomizer lip (36) in an end region (34), a fuel supply arrangement (52, 50) for supplying fuel to the flow guide surface (28) at a distance from the atomizer lip (36), characterized in that the fuel supply arrangement (52, 50) in the flow guiding element (16) comprises a fuel delivery depression (50) into which a fuel supply channel arrangement (52) opens in a junction area. Atomizing nozzle according to claim 1,
characterized in that at least one fuel distribution element (58) is provided in the fuel delivery depression (50) for conveying fuel fed into the fuel delivery depression (50) via the fuel supply channel arrangement (52) to areas of the fuel delivery depression (50) which are further away from the confluence area. Atomizing nozzle according to claim 2,
characterized in that the fuel distribution element (58) is designed to convey the fuel using a capillary action. Atomizing nozzle according to claim 3,
characterized in that the fuel distribution element (58) cooperates with a fuel delivery depression (50) delimits a capillary flow channel arrangement (66) in the surface area (56, 60, 62) delimiting the flow guide element (16). Atomizing nozzle according to one of claims 2 to 4,
characterized in that the fuel distribution element (58) has at least one fuel passage area (64) to enable fuel to escape from the fuel delivery depression (50). Atomizing nozzle according to one of claims 2 to 5,
characterized in that the fuel distribution element (58) has at least one elongate element (59) extending along the fuel delivery depression (50). Atomizing nozzle according to claim 6,
characterized in that the fuel distribution element (58) has a plurality of elongate elements (69, 70) which abut one another and form a capillary flow channel arrangement (72) between them. Atomizing nozzle according to one of claims 2 to 7,
characterized in that the at least one fuel distribution element (58) is formed from porous material (72). Atomizing nozzle according to one of claims 1 to 8,
characterized in that the confluence area comprises at least one confluence point at which a fuel supply duct section (54) of the fuel supply duct arrangement (52) opens into the fuel dispensing depression (50). Atomizing nozzle according to one of claims 1 to 9,
characterized in that the confluence region is formed in a bottom region (56) of the fuel discharge depression (50) which is essentially radially delimiting the same. Atomizing nozzle according to one of claims 1 to 10,
characterized in that the fuel supply channel arrangement (52) comprises at least one fuel supply channel section (54) which opens substantially tangentially into the fuel delivery depression (50) formed in the manner of a ring or ring segment. Atomizing nozzle according to one of claims 1 to 11,
characterized in that the flow guiding element (16) is constructed essentially concentrically to a central axis (A) and in that the fuel delivery depression (50) is designed as an annular groove-like depression arranged essentially concentrically with respect to the central axis (A). Atomizing nozzle according to one of claims 1 to 12,
characterized in that the flow guide element (16) separates an outer swirl flow (S _a ) from an inner swirl flow (S _i ) and in that the flow guide surface (28) is a surface of the flow guide element (16) guiding the inner swirl flow (S _i ). Atomizing nozzle according to claim 13,
characterized in that the flow guide element (16) is surrounded in an axial end region (34) of the atomizer lip (36), which together with the flow guide element (16) surrounds the outer swirl flow (S _a ) and guides the outer flow guide element (18). Atomizer nozzle according to claims 13 and 14,
characterized in that the flow guiding element (16) surrounds an inner flow guiding element (14) guiding the inner swirl flow (S _i ) at least in regions, and in that the fuel delivery depression (50) at least partly in a surrounding the inner flow guiding element (14) Area of the flow guide element (16) is formed. Atomizing nozzle according to one of claims 13 to 15,
characterized in that the entire combustion air used to burn the fuel atomized by means of the atomizer nozzle (10) is supplied by the outer swirl flow (S _a ) and the inner swirl flow (S _i ). Atomizer nozzle according to one of Claims 1 to 16, characterized by an ignition element (80) for igniting a combustion air / fuel mixture in a volume area which is at least partially delimited by the flow guiding element (16). Atomizer nozzle for a burner, in particular for a vehicle heater, comprising: a flow guide element (16) providing a flow guide surface (16), which has an atomizing lip (36) in an end region (34), the flow guide element (16) separating an outer swirl flow (S _a ) from an inner swirl flow (S _i ), a fuel supply arrangement (52, 50) for supplying fuel to the flow guide surface (28) at a distance from the atomizer lip (36), optionally in conjunction with one or more of the features of the preceding claims, characterized in that the entire combustion air used to burn the fuel atomized by means of the atomizer nozzle (10) is supplied by the outer swirl flow (S _a ) and the inner swirl flow (S _i ). Atomizer nozzle for a burner, in particular for a vehicle heater, comprising: a flow guide element (16) providing a flow guide surface (28), which has an atomizer lip (36) in an end region (34), a fuel supply arrangement (52, 50) for supplying fuel to the flow guide surface (28) at a distance from the atomizer lip (36), optionally in conjunction with one or more of the features of the preceding claims, characterized by an ignition element (80) for igniting a combustion air / fuel mixture in a volume area which is at least partially delimited by the flow guiding element (16). Atomizing nozzle according to claim 19,
characterized in that the flow guide element (16) separates an outer swirl flow (S _a ) from an inner swirl flow (S _i ) and in that the ignition element (80) for igniting the combustion air / fuel mixture in a central position in the inner swirl flow (S _i ) trained backflow area (R) is effective. A vehicle heater comprising a burner with an atomizing nozzle according to any one of claims 1 to 20. Device for treating an exhaust gas aftertreatment system, in particular for the thermal regeneration of a particle filter or / and for heating a catalyst, comprising a burner with an atomizing nozzle according to one of claims 1 to 20. Device for generating process gases from liquid fuels, e.g. Gasoline, diesel, heating oil, methanol, ethanol, comprising a burner with an atomizing nozzle according to one of claims 1 to 20.

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