EP1340940A1 - Atomizing nozzle for a burner, especially for a heating apparatus used in an automobile - Google Patents

Abstract

A fuel feed channel section, formed on a fuel feeder in a second flow guide (36), is opened towards the second flow guide surface area having a surface normal radial component not equal to zero. The fuel feeder sends fuel through a first flow space area (30) to the flow guide surface of a first flow guide (34). An Independent claim is included for a vehicle heater.

Description

The present invention relates to an atomizer nozzle for a burner, in particular for a heater used on a vehicle, comprising a first flow guide element providing a flow guide surface, that in an axial end region with respect to a nozzle center axis has an atomizer lip, one together with the first Flow guide element a first leading to the atomizer lip Second flow guiding element delimiting the flow space area and a fuel supply arrangement in the second flow guide element for applying fuel through the first flow area through onto the flow guide surface of the first flow guide element.

EP 0 910 776 B1 describes a burner that can be used in gas turbines known. In this burner fuel is injected through an injector a flow guide surface ending in an atomizer lip Flow guide element injected. The crosses under high Pressure fuel exiting the injector to the atomizer lip leading flow space area before moving to further distribution and Atomization onto the flow guide surface of the flow guide element arrives. The fuel is from a surface of the Atomizer nozzle emitted, which essentially to a nozzle center axis has parallel surface normal. The also partially radially directed Fuel flow must be delivered at high pressure to ensure that it is not carried away by the air flow, before hitting the flow guide surface of the flow guide member arrives.

Especially when used in the automotive sector, the supply of Critical fuel under high pressure. The reason for this is that the fuel supply lines frequently have to be guided past components that have very high temperatures. A leak in the area of these lines would result in the fuel under high pressure leaks in the area of this leak and is atomized if necessary. This pulls the danger of immediate fuel ignition in the area of such Leaks after themselves.

It is the object of the present invention, a generic atomizing nozzle to be further developed in such a way that it is highly reliable ensures reliable fuel distribution or atomization.

According to the present invention, this object is achieved by a Atomizer nozzle for a burner, in particular for a vehicle used heater, comprising a a flow guide surface providing first flow guide element, which in an axial End area has an atomizer lip with respect to a nozzle center axis, one together with the first flow guiding element Atomizing lip guiding the first flow space area second flow guide element and a fuel supply arrangement in the second flow guide element for applying fuel through the first flow chamber area onto the flow guide surface of the first flow guiding element.

According to the invention, it is further provided that the fuel supply arrangement at least one fuel supply channel section in the has a second flow guide element, which fuel supply channel section to a surface area of the second flow guide element is open, the non-zero surface normal radial component having.

In the present invention, it is ensured that the fuel without the need to feed under high pressure with just one Radial component from the at least one fuel supply channel section exit. The risk of fuel particles then falling on the Flow guide surface of the first flow guide element arrive in the air flow flowing through the flow chamber area carried along is essentially switched off.

For example, it can be provided that the second flow guide element downstream of the opening area of the at least one fuel supply channel section tapering with respect to the nozzle center axis is trained.

Alternatively, however, it is also possible for the second flow guide element downstream of the opening area of the at least one fuel supply channel section widening with respect to the nozzle center axis is trained. The expanding configuration of the second flow guide element can then be used on the second Flow guide element downstream of the opening area of the at least one fuel supply channel portion a fuel delivery lip provided. The one emerging from the fuel supply channel section So fuel moves along the radially widening Surface of the second flow guide element and comes under Carrying out a preliminary distribution in the circumferential direction to the fuel delivery lip, from which it then continues radially outward to the flow guide surface of the first flow guide element is moved.

Reliable transport of the fuel along the second flow guiding element towards the fuel dispensing lip thereby ensuring that the surface normal in the surface area of the second flow guide element to the first one Current flowing through the flow chamber area essentially in the opposite direction is.

According to a particularly advantageous embodiment, one can, if possible uniform fuel supply can be achieved in that in the second flow guide element a plurality of fuel supply channel sections is formed on each other in the circumferential direction with respect to a nozzle center axis successive opening areas to respective surface areas of the second flow guide element are open. It is also advantageous if at least a fuel supply channel section substantially toward the Surface normals open into the surface area.

To ensure reliable transportation of the second flow guide element to support the amount of fuel released radially to the outside, it is proposed that in order to generate a swirl flow in the first Flow space area at least one deflection element is provided. By providing a swirl in the first flow area flowing air stream ensures that by generation corresponding centrifugal forces from the second flow guide element dispensed fuel particles radially outwards in the direction of Flow guide surface of the first flow guide element to be hurled.

To with the atomizer nozzle according to the invention for a uniform and reliable atomization of the first flow guiding element to supply fuel, it is suggested that the first Flow guide element together with a third flow guide element delimits a second flow area.

In another aspect, the present invention relates to a heater with an atomizing nozzle according to the invention. With this heater a fuel supply system can then be provided for supplying Fuel to the at least one fuel supply channel section a pressure of up to 2.0 bar, preferably up to 1.5 bar, above which in pressure prevailing in the first flow space region.

Fig. 1

eine schematische Längsschnittansicht eines Abgasführungssystems in einem Kraftfahrzeug, in welchem ein Heizgerät mit einer erfindungsgemäßen Zerstäuberdüse vorgesehen ist;

Fig. 2

eine vergrößerte Prinzip-Längsschnittansicht einer ersten Ausgestaltungsform der erfindungsgemäßen Zerstäuberdüse;

Fig. 3

eine der Fig. 2 entsprechende Ansicht einer alternativen Ausgestaltungsform der erfindungsgemäßen Zerstäuberdüse.

The present invention is described below with reference to the accompanying drawings. It shows:

Fig. 1

is a schematic longitudinal sectional view of an exhaust gas routing system in a motor vehicle, in which a heater is provided with an atomizing nozzle according to the invention;

Fig. 2

an enlarged principle longitudinal sectional view of a first embodiment of the atomizing nozzle according to the invention;

Fig. 3

a view corresponding to FIG. 2 of an alternative embodiment of the atomizing nozzle according to the invention.

Before in the following with reference to FIGS. 2 and 3, the construction atomizer nozzles according to the invention is described in detail first described an overall system with reference to FIG. 1, in which a generally designated 10 heating burner, the one according to the invention Atomizer nozzle 12 is provided. The heating burner 10 is in an expanded section 14 of an exhaust gas routing system 16 in one Motor vehicle arranged. The one supplied via a fuel line 18 Fuel is atomized in the atomizer nozzle 12 and together with the combustion air also supplied via the atomizer nozzle 12 in one Combustion chamber 20 burned. By an ignition element 22, for example one Glow plug, this combustion is triggered. The heater 10 from the upstream and then the radially outward flow Combustion exhaust gases flow through from an internal combustion engine cone-shaped perforated plate 24 and are thereby by the Combustion chamber 20 leaving heated combustion gases from the heating burner 10 heated so that it is further downstream for regeneration of a particle filter.

It goes without saying that the heating burner 10 according to the invention also has the atomizer nozzle 12 provided therein also in other system areas, such as. an auxiliary heater, an auxiliary heater or a so-called Kat heater can be used to preheat a catalyst.

The structure of the atomizing nozzle 12 is still with reference to FIG. 1 executed that this radially from the outside via an air supply area 26 Air is supplied, which is then in an annular space 28 on two Flow space areas 30, 32 is distributed. The two flow space areas 30, 32 are through a first flow guiding element 34 separated from each other. Together with one that can also be considered as a floor part second flow guide element 36 delimits the first flow guide element 34 the first flow space region 30, while the first flow guide element 34 together with a third Flow guiding element 38 the second flow space region 32 limited. The detailed structure of this atomizing nozzle 12 is first further described with reference to FIG. 2.

The first flow guide element 34 can be seen in detail in FIG. 2, the respective flow guide surfaces 40 on both sides, 42 provides. The radially inner flow guide surface 40 delimits together with a flow guide surface 44 of the second flow guide element 36 the first flow space region 30. The radially outer flow guide surface 42 bounded by a flow guide surface 46 of the third flow guide element 38 the second flow space area 32. The two flow guide surfaces 40, 42 of the first flow guide element 34, which with respect to a nozzle center axis A essentially rotationally symmetrical trained and tapered asymptotically, end in an approximately cylindrical end portion thereof in an atomizer lip 48.

Both in the first flow space region 30 and in the second flow space region 32, blade-like deflection elements 50, 52 are provided between the components delimiting these two flow space regions 30, 32, which ensure that the air flow entering radially inward from the annular space 28 receives a circumferential flow direction component, so that an inner swirl current S _i and an outer swirl current S _a form.

A fuel supply assembly, generally designated 54, includes starting from a central line 56 several leading radially outwards Fuel supply channel sections 58. These are in respective opening areas 60 to the flow guide surface 44 of the second flow guide element 36 open. In the areas where the opening areas 60 lie, the flow guide surface 44 has such Orientation on that the surface normal F is a non-zero Have radial component, i.e. is not directed purely axially. you further recognizes that the fuel supply channel sections 58 at least have an extension direction near their opening areas 60, which is approximately parallel to the surface normal F. Downstream of the Opening areas 60 is the second flow guide element 36 its flow guide surface 44 is still tapered.

When fuel is introduced via the central line 56 and then the fuel supply channel sections 58, the fuel is already released into the flow space region 30 with a substantial radial component. The radial movement of the fuel is further supported in that it is detected by the inner swirl flow S _i when it exits the opening areas 60 and also experiences a circumferential movement component through this. Due to the centrifugal forces generated in the process, the fuel is increasingly thrown radially outward so that it finally reaches the flow guide surface 40 of the first flow guide element 34 in a reliable manner. A fuel film 62 is formed there, which then moves under the influence of the inner swirl flow S _i flowing through the flow space region 30 in the direction of the atomizer lip 48. It is atomized there by the shear action of the two swirl flows S _i and S _a , in order then to produce an ignitable mixture of atomized fuel and combustion air downstream of the atomizer lip 38. The entire combustion air is preferably supplied in the form of the two swirl currents S _i and S _a .

In the atomizer nozzle shown in Fig. 2 it is ensured that solely by specifying the direction of exit of the fuel and reinforced through the centrifugal forces then acting on it a safer one Guaranteed transport in the direction of the first flow guide element 34 is. The supply of the fuel at high speed, i.e. under high pressure, is not required, which enables that upstream fuel supply system comparatively simple and, for example, the fuel supply under the effect of a Dosing pump takes place, which is able to use a fuel Supply pressure of up to 1.5 or 2.0 bar above that pressure, which is the exit of the fuel from the fuel supply passage sections 58 counteracts, that is, generally the pressure that occurs in Area of the combustion chamber 20 or the flow chamber area 30 predominates.

A modified embodiment of the atomizing nozzle according to the invention 12 is shown in FIG. 3. Components that already exist correspond to the described components in terms of structure and function, are identified by the same reference numerals.

It can be seen that the second flow guiding element 36 is included here an end piece 64 is formed which a further section 44 ' Flow guide surface of the second flow guide element 36 provides. This end piece 64 can, for example, be a separate component can be provided, however, with the section also recognizable in FIG. 1 of the second flow guide element 36 is integrally formed his. It can be seen that in the transition area between the two flow guide surfaces 44, 44 'a radial jump or transition is available. While the flow guide surface 44 in the flow direction tapering towards the nozzle center axis A. is formed, the flow guide surface 44 'begins there step-like transition area with a small radius expanding radially. The flow guide surface 44 ends at one with the reference symbol 66 designated fuel delivery lip, due to the approximately rotationally symmetrical configuration of the end piece 64 approximately has a ring-like contour. This takes in the direction downstream the curvature of the flow guide surface 44 ', so that in the area of the discharge lip 66 the flow guide surface 44 ' an essentially axially directed and in the representation of FIG on the left, ie in the direction of the surface normal directed away from the atomizing nozzle 48 having.

In this end piece 64 the fuel feed channel sections 58 are again formed, the opening areas 60 of which now lie on the flow guide surface 44 '. Here too, non-zero radial extension components of the surface normal can be seen in those areas of the flow guidance surface 44 'in which the opening areas 60 are formed. Due to the widening shape of the flow guiding surface 44 ′, the surface normals F here are essentially opposite to the inner swirl flow S _i when the circumferential flow component of this swirl flow is neglected. The fuel emerging from the fuel supply channel sections 48 is entrained by the internal swirl flow S _i , a back pressure being generated here in particular due to the widening shape of the flow guide surface 44 ′ that the fuel is reliably conveyed in the direction of the fuel discharge lip 66. During this delivery process, the fuel is already distributed in the circumferential direction, so that an approximately uniform fuel particle flow is directed radially outward from the fuel delivery lip 66 onto the flow guide surface 40 of the first flow guide element 34. The circumferential flow component of the inner swirl flow S _i again makes a significant contribution here.

Both of the embodiments described above have the Advantage on that even when the fuel supply is comparatively low Pressure a reliable delivery to the outside can be done. Essential for this is that the fuel already has a certain radial flow direction component what is released to the outside the centrifugal forces introduced by means of the swirl flow is supported. It goes without saying that at the previous described atomizer nozzles still made various modifications can be. For example, the fuel supply channel sections 58 in a groove-like recessed area of the second flow guide element 36 or flow guide surfaces 44, 44 ' flow into the same. This groove-like depression can be in the circumferential direction be circumferential, so that a pre-distribution is already in this groove-like depression of the fuel can take place in the circumferential direction.

Claims (11)

Atomizer nozzle for a burner, in particular for a heater used on a vehicle, comprising: a first flow guide element (34) providing a flow guide surface (40), which has an atomizer lip (48) in an axial end region with respect to a nozzle center axis (A), together with the first flow guide element (34) a second flow guide element (36) delimiting a first flow chamber region (30) leading to the atomizer lip (48), a fuel supply arrangement (54) in the second flow guide element (36) for applying fuel through the first flow space region (30) to the flow guide surface (40) of the first flow guide element (34), characterized in that the fuel supply arrangement (54) has at least one fuel supply channel section (58) in the second flow guide element (36), which fuel supply channel section (58) is open to a surface area (44; 44 ') of the second flow guide element (36) which is one of Has zero different surface normal radial component. Atomizing nozzle according to claim 1,
characterized in that the second flow guide element (36) downstream of an opening area (60) of the at least one fuel supply channel section (58) is designed to taper with respect to the nozzle center axis (A). Atomizing nozzle according to claim 1,
characterized in that the second flow guide element (36) downstream of an opening region (60) of the at least one fuel supply channel section (58) is designed to widen with respect to the nozzle center axis (A). Atomizing nozzle according to claim 3,
characterized in that the second flow guide element (36) has a fuel delivery lip (66) downstream of the opening region (60) of the at least one fuel supply channel section (58). Atomizing nozzle according to claim 4,
characterized in that the surface normal (F) in the surface area (44 ') of the second flow guiding element (36) is essentially opposite to a current flowing through the first flow space area (30). Atomizing nozzle according to one of claims 1 to 5,
characterized in that in the second flow guiding element (36) a plurality of fuel supply channel sections (58) are formed, which in the circumferential direction with respect to a nozzle center axis (A) successive opening areas (60) to respective surface areas (44; 44 ') of the second flow guiding element (36) are open. Atomizing nozzle according to one of claims 1 to 6,
characterized in that the at least one fuel supply duct section (58) opens into the surface region (44; 44 ') essentially in the direction of the surface normal (F). Atomizing nozzle according to one of claims 1 to 6,
characterized in that at least one deflection element (50) is provided for generating a swirl flow in the first flow space region (30). Atomizing nozzle according to one of claims 1 to 8,
characterized in that the first flow guide element (34), together with a third flow guide element (38), delimits a second flow space region (32). Heating device comprising an atomizing nozzle (12) according to one of the preceding claims. Heater according to claim 10,
characterized in that a fuel supply system is provided for supplying fuel to the at least one fuel supply channel section (58) at a pressure of up to 2.0 bar, preferably up to 1.5 bar, above the pressure prevailing in the first flow space region (30).

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