阅读说明：本技术 具有泡沫金属加热元件的废气加热装置 (Exhaust gas heating device with metal foam heating element ) 是由 冯婷 扬妮克·富尔科多特 于 2020-11-19 设计创作，主要内容包括：一种加热装置(10)包括：泡沫金属形式的加热元件(16)；由沿着纵向轴线(X)延伸的侧壁(14)限定的壳体(12),在其中容纳泡沫金属(16)；设置在泡沫金属(16)与壳体(12)之间的电绝缘装置(18)；至少一个电极(22)。泡沫金属(16)包括被构造为接收至少一个电极(22)的区域(24)。(A heating device (10) comprising: a heating element (16) in the form of a metal foam; a housing (12) defined by a side wall (14) extending along a longitudinal axis (X), in which a metal foam (16) is housed; an electrical insulation means (18) disposed between the metal foam (16) and the housing (12); at least one electrode (22). The metal foam (16) includes a region (24) configured to receive at least one electrode (22).)

1. An exhaust gas heating device (10) for a heat engine exhaust line, comprising:

-a metal foam (16) forming a heating element;

-a housing (12) defined by a side wall (14) extending along a longitudinal axis (X), in which the metal foam (16) is housed;

-electrical insulation means (18) arranged between said metal foam (16) and said shell (12);

-at least one electrode (22),

characterized in that the metal foam (16) comprises a region (24) configured to receive the at least one electrode (22).

2. The exhaust gas heating device (10) according to claim 1, characterized in that the metal foam (16) comprises a foam preform (16a) having a uniform mesh structure throughout its volume.

3. Exhaust gas heating device (10) according to claim 1 or 2, characterized in that it comprises a protective layer (28) formed of a first liquid material which has soaked the outer circumference of the metal foam (16) before drying, the electrical insulation means (18) comprising at least one ring element (26) surrounding the protective layer (28).

4. Exhaust gas heating device (10) according to claim 1 or 2, characterized in that it comprises two annular retaining elements (20) for retaining the metal foam (16), arranged on both sides of the metal foam (16) in the direction of the longitudinal axis (X) and each fixed on the housing (12).

5. Exhaust gas heating device (10) according to claim 4, characterized in that at least one of the retaining elements (20) comprises a fastening tab (30) extending towards the longitudinal axis (X), and the housing (12) comprises for each fastening tab (30) a welding hole (32) through which the corresponding fastening tab (30) is welded to the housing (12).

6. A heat engine exhaust line, characterized in that it comprises an exhaust gas heating device (10) according to claim 1.

7. Vehicle, in particular motor vehicle, characterized in that it comprises a heat engine exhaust line according to claim 6.

8. A manufacturing method for an exhaust gas heating device (10) according to claim 1, characterized in that the metal foam (16) is manufactured according to the following steps:

-making a foam preform (16 a);

-filling the foam preform (16a) with a first liquid metal having a first density;

-drying the foam preform (16a) filled with metal;

-a first sintering of said foam preform (16a) filled with metal;

-after said first sintering, injecting a second liquid metal having a second density higher than said first density in at least one region (24) of the peripheral portion of said foam preform (16a) filled with metal and sintered;

-a second sintering of the foam preform (16a) including the region (24).

9. The manufacturing method according to claim 8, characterized in that the manufacturing of the metal foam (16) comprises cutting the metal-filled and sintered foam preform (16a) into a first shape (16b) after the first sintering and before injecting the second liquid metal, the two areas injected into the second liquid metal being located on the peripheral portion of the first shape (16 b).

10. The manufacturing method according to claim 9, characterized in that the dimensions of the first shape (16b) are larger than the dimensions of a desired final shape, the manufacturing of the metal foam (16) comprising cutting the first shape (16b) after the second sintering to obtain the desired final shape.

Technical Field

The invention relates to an exhaust gas heating device for equipping an exhaust gas line of an internal combustion engine, in particular of a vehicle.

Background

From the prior art, an exhaust line of an internal combustion engine is already known, which comprises a device for reducing pollutant particles (in particular nitrogen oxides NOx) to harmless particles (in particular nitrogen N)₂And water H₂O) catalytic purification apparatus. For this purpose, the exhaust gases are passed through a catalytic purification unit.

It should be noted that the efficiency of the catalytic cleaning unit is optimal when the reaction is carried out at high temperatures. Therefore, the reaction efficiency is poor during cold start, and thus more pollutant particles are discharged.

In order to solve this drawback, one solution consists in equipping the exhaust line with exhaust gas heating means for heating the exhaust gases before they pass through the purification unit until the engine emits sufficiently hot gases. The heating device is disposed upstream of the purification unit.

One known example of a heating device includes a heating element formed of a foamed metal through which an electric current flows to heat it by joule effect. The metal foam is arranged to let the exhaust gases pass through it, whereby the exhaust gases are heated before entering the purification unit. The current is provided by electrodes electrically connected to the metal foam.

However, such heating devices are not entirely satisfactory, in particular because it is difficult to form an electrical connection between the electrode and the metal foam.

Disclosure of Invention

The object of the present invention is in particular to solve the above-mentioned drawbacks by providing a heating device that enables a simple and reliable formation of the electrical connection between the electrode and the metal foam.

To this end, the invention relates in particular to an exhaust gas heating device for an exhaust line of a heat engine, comprising:

-a heating element in the form of a foamed metal;

-a housing defined by side walls extending along a longitudinal axis, containing a metal foam therein;

-electrical insulation means arranged between the metal foam and the housing;

-at least one electrode, which is,

wherein the metal foam includes a region configured to receive at least one electrode.

Since the region of the metal foam is shaped to receive the electrode, the device does not require additional connecting elements between the electrode and the metal foam.

The heating device according to the invention may also comprise one or more of the following features considered alone or according to all technically feasible combinations:

the metal foam comprises a foam preform having a uniform mesh structure throughout its volume.

The heating means comprise a protective layer formed by a first liquid material which has been impregnated with the outer peripheral portion of the metal foam before drying, and the electrical insulation means comprise at least one annular element surrounding the protective layer.

The heating device comprises two annular holding elements for holding the metal foam, which are arranged on both sides of the metal foam in the direction of the longitudinal axis and are each fixed to the housing.

The at least one retaining element comprises a fastening tab extending towards the longitudinal axis, and the housing comprises, for each fastening tab, a welding hole through which the corresponding fastening tab is welded to the housing.

The invention also relates to an exhaust line of a heat engine, characterized in that it comprises a heating device as defined above.

The invention also relates to a vehicle, in particular a motor vehicle, characterized in that it comprises an exhaust line as defined above.

The invention finally relates to a method for producing an exhaust gas heating device, characterized in that a metal foam is produced according to the following steps:

-making a foam preform;

-filling the foam preform with a first liquid metal having a first density;

-drying the metal-filled foam preform;

-a first sintering of the metal-filled foam preform;

-after the first sintering, injecting a second liquid metal having a second density higher than the first density in at least one region of the peripheral portion of the metal-filled and sintered foam preform;

-a second sintering of the foam preform comprising said area.

Advantageously, the production of the metal foam comprises cutting the metal-filled and sintered foam preform into a first shape after the first sintering and before the injection of the second liquid metal, the two areas of injection of the second liquid metal being located on the peripheral portion of the first shape.

Optionally, the first shape has a size larger than the size of the desired final shape, and the manufacturing of the metal foam comprises cutting the first shape after the second sintering to obtain the desired final shape.

Drawings

The various aspects and further advantages of the invention will emerge from the following description, provided purely by way of non-limiting example, made with reference to the accompanying drawings, in which:

figure 1 is a perspective view of a heating device according to a first embodiment of the invention;

figure 2 is an exploded perspective view of the heating device of figure 1;

figure 3 is a perspective view of a detail of a preform for the production of the metal foam of the heating device of figure 1;

figure 4 schematically shows the metal foam during one step of its manufacture of the heating device of figure 1 in a top view;

figure 5 is an exploded perspective view of a heating device according to a second embodiment of the invention.

Detailed Description

Fig. 1 and 2 show a heating device 10 according to an exemplary embodiment of the present invention.

The heating device 10 is adapted to being arranged upstream of the exhaust gas purification device in the exhaust line of the heat engine. The heat engine is, for example, a heat engine of a vehicle, in particular of a motor vehicle, but may be any other heat engine in a variant.

The cleaning device comprises, in a manner known per se, a catalytic cleaning unit to allow the reduction of pollutant particles, in particular nitrogen oxides NOx, to harmless particles, in particular nitrogen N₂And water H₂O). The reduction reaction is more efficient at high temperatures, so the heating device 10 is used to heat the exhaust gases upstream of the purification device, in particular during a cold start of the heat engine.

The heating device 10 comprises a housing 12 formed by a substantially cylindrical wall 14 extending along a longitudinal axis X. Preferably, the wall 14 has a cylindrical general shape defined around the longitudinal axis X, with a circular, elliptical or rectangular base with rounded corners.

The heating device 10 further comprises a heating element 16 housed in the casing 12, electrical and thermal insulation means 18 radially interposed between the heating element 16 and the wall 14 of the casing 12, and a retaining element 20. The heating device 10 also comprises at least one electrode 22 electrically connected to the heating element 16 for passing an electric current in the heating element 16 to heat it by joule effect. Preferably, the heating means comprise two electrodes 22.

Preferably, each electrode 22 comprises a conductive core 22a surrounded by an insulating sheath 22 b.

The conductive core 22a is made of, for example, a metal, particularly a metal selected from iron-chromium-aluminum (FeCrAl) and alloys thereof, nickel-chromium (NiCr) and alloys thereof, stainless steel,Or silicon carbide.

The insulating sheath 22b is made of, for example, magnesium oxide MgO or aluminum oxide Al₂O₃And (4) preparing.

The insulating sheath 22b is preferably in turn used for weldable materials (in particular for welding to the housing 12)Or NiCr) is formed around the outer jacket 22 c. The outer cover 22c is electrically isolated from the conductive core 22a by the insulating sheath 22 b.

The heating element 16 is formed of a metal foam, the manufacture of which according to the invention will be described later.

Preferably, the metal foam 16 is made of an iron-chromium-aluminum (FeCrAl) alloy or a nickel-chromium (NiCr) alloy. The density of the metal foam 16 is between 8% and 11% inclusive and the thickness (considered in the direction of the longitudinal axis X) is between 15mm and 30mm inclusive.

The metal foam 16 has at least one region 24 shaped to receive one of the at least one electrode 22. The region 24 may be disposed at any suitable location on the metal foam 16. In the depicted example, the metal foam 16 includes two regions 24 disposed at a peripheral portion of the metal foam 16 and disposed opposite each other. In one variation, the region 24 may be provided at or near the center of the metal foam 16. According to another variant, the areas 24 may not be arranged opposite each other at the peripheral portion of the metal foam 16, but such that the electrodes 22 form an angle with respect to each other, for example less than or equal to 45 ° or between 120 ° (inclusive) and 180 ° (inclusive).

Preferably, each region 24 is a dense weld region 24 for coupling to a respective one of the electrodes 22 by welding. In other words, the density of the weld area 24 is sufficient to allow welding of the corresponding electrode 22.

Each region 24 preferably extends a depth of at least 5mm within the metal foam 16. Furthermore, each region 24 preferably extends over a diameter greater than twice the diameter of the conductive core 22a of the electrode 22. Thus, for a conductive core 22a having a diameter of about 6mm, the corresponding region 24 has a diameter of at least 12mm, such as about 18 mm.

The insulating means 18 comprises at least one insulating element 26, preferably two insulating elements 26, at least partially surrounding the outer circumference of the heating element 16. More specifically, two insulating elements 26 are provided to expose the dense welding area 24.

Advantageously, the insulating element 26 comprises edges 26a which together define a recess 27 in which the peripheral portion of the heating element 16 is housed. Thus, the rims 26a frame the outer peripheral portion of the heating element 16 on both sides in the direction of the longitudinal axis X of the heating element 16.

The insulating element 26 in particular ensures radial tightness against the exhaust gases, so as to ensure that the exhaust gases pass through the heating element 16 only in the direction of the axis X.

Each insulating element 26 is formed, for example, by a fibre mesh made of electrically insulating material. Any electrically insulating material is conceivable.

Advantageously, the protective layer 28 covers the outer periphery of the heating element 16. The protective layer 28 serves to protect the insulating element 26 from the aggressive porous edges of the metal foam 16. Thus, once the protective layer 28 is applied, the heating element 16 has a smooth outer perimeter and no longer has a porous and aggressive outer perimeter. Thus, the life of the insulating member 26 is improved.

According to an exemplary embodiment, the protective layer 28 is made of a metal, such as the same metal that forms the metal foam 16. In a variant, the protective layer 28 may be made, for example, of ceramic or magnesium oxide MgO. According to another modification, the protective layer 28 may be made of any other suitable material as long as the outer peripheral portion of the heating element 16 can be made smooth.

The holding element 20 serves to hold the heating element 16 and the insulating element 26 in the direction of the longitudinal axis X. More specifically, in the example depicted, the retaining element 20 retains the insulating element 26, and the insulating element 26 retains the heating element 16. The retaining elements 20 are preferably substantially identical.

Each retaining element 20 has an annular general shape with a peripheral profile 20a intended to be fixed to the wall 14 of the casing 12 (in particular to the inner surface of this wall 14) and to have a sufficient extension in the radial direction so as to extend across a portion of the heating element 16. The holding element 20 thus clamps the heating element 16 on both sides of the heating element 16 in the direction of the longitudinal axis X.

Each retaining element 20 delimits a central opening 21 which enables the passage of the exhaust gases towards the heating element 16.

Each retaining element 20 comprises, on its peripheral profile 20a, a plurality of fastening tabs 30, for example three to eight fastening tabs, preferably four or six fastening tabs 30, evenly distributed on the peripheral profile 20 a. The securing tab 30 extends away from the heating element 16 parallel to the longitudinal axis X. Thus, a welding operation can be performed on these heating elements 16 without the heat emitted by the welding damaging the metal foam 16.

The wall 14 of the housing 12 comprises, for each fastening tab 30, a welding hole 32, by means of which welding hole 32 the corresponding fastening tab 30 is welded to the wall 14. These weld holes 32 may facilitate access to the securing tabs 30 and reduce the welding time of the securing tabs 30.

The welding holes 32 preferably have a circumferentially extending rectangular overall shape to achieve an optimal welding surface along the contour of each welding hole 32.

It should be noted that the metal foam 16 is thus not welded directly to the housing 12, but is axially retained by the retaining element 20, which is welded to the housing 12. Thus, all difficulties associated with the welding of the metal foam are avoided.

The wall 14 of the housing 12 also has passage openings 34 for the electrodes 22, each passage opening 34 preferably being disposed opposite a respective one of the weld regions 24 of the heating element 16. Alternatively, the passage opening 34 is offset with respect to the welding area 24. Each passage opening 34 preferably has an outer peripheral edge 36 extending in a radial direction towards the outside of the casing 12, so that the corresponding electrode 22 can be well retained.

A method for manufacturing the heating apparatus 10 will now be described.

The method first includes making a metal foam.

The manufacture of the metal foam 16 includes the step of manufacturing a foam preform 16a, which is partially shown in fig. 3. The foam preform 16a according to the present invention preferably has a mesh structure uniform over its entire volume. As shown in fig. 3, the mesh structure comprises, for example, a mesh 37 having a substantially polyhedral shape, in particular a hexagonal shape. The grids 37 communicate with each other through holes 38. Advantageously, the size of the grid is between 0.4mm (inclusive) and 5mm (inclusive).

Such a foam preform 16a is for example manufactured by an additive manufacturing method, in particular 3D printing. The foam preform 16a is made of, for example, polyurethane.

Due to the predetermined and uniform structure of the foam preform 16a, its properties are readily known (reproducible), and are similar throughout the foam preform 16 a.

Alternatively, the foam preform 16a has a non-uniform structure (a conventional sponge-type preform).

It should be noted that the dimensions of the foam preform 16a are preferably larger than the dimensions of the final metal foam 16.

Next, the method includes filling the foam preform 16a with a first liquid metal having a first density. The first liquid metal may be a molten metal or, in a variant, a fluid with metal particles (metal slurry). The first density is for example between 4% and 15% inclusive of the density of the metal foam 16.

The foam preform 16a is thus saturated with the first liquid metal, which thus covers the material forming the foam preform 16 a.

Next, the method includes drying the metal-filled foam preform 16a until the first metal is no longer in a liquid state and thus remains adhered to the foam preform 16 a.

Next, the method includes first sintering the metal-filled and dried foam preform 16 a. Sintering refers to heating the metal-filled and dried foam preform below the melting temperature of the first metal to improve the adhesion of the first metal.

Preferably, the manufacture of the metal foam 16 includes cutting the metal filled and sintered foam preform 16a into a first shape, the dimensions of which are still larger than the dimensions of the final shape of the metal foam 16. The first shape is for example a cuboid, in particular with a square base. This first shape is shown in fig. 4, indicated by reference numeral 16 b.

Advantageously, as shown in fig. 4, the production of the metal foam 16 comprises, after the first sintering, the injection of a second liquid metal having a second density greater than the first density into two separate areas on the peripheral portion of the sintered and cut first shape 16b filled with metal.

The second liquid metal may be a molten metal or, in a variant, a fluid with metal particles (metal slurry). The second density is, for example, greater than 90% of the density of the metal foam 16.

Preferably, the second liquid metal is made of the same material as the first liquid metal, in particular of a FeCrAl or NiCr alloy, but with a density greater than the density of the first liquid metal.

The area in which the second liquid metal is injected is the weld area 24.

Next, the method includes a second sintering to improve the adhesion of the solder region 24.

Alternatively, the weld region 24 is not formed by injecting a second liquid metal into the metal foam 16. In this case, the method comprises forming at least one blind hole in the metal foam 16 by piercing, and then filling the blind hole with the material forming the region 24, in particular with the second liquid metal.

According to another variant, the blind holes are not formed by piercing, but are formed after the metal foam 16 has been formed. More specifically, the preform 16a already comprises blind holes in this case.

Next, the manufacturing of the metal foam 16 comprises cutting the first shape 16b to obtain the desired final shape, which substantially corresponds to the shape of the shell 12, in particular a cylindrical shape, for example with a circular, oval or rectangular bottom with rounded corners.

It should be noted that the metal foam 16 obtained using the method according to the invention is easily identifiable due to its uniform mesh structure and/or the presence of the welding zones 24.

Preferably, the manufacture of the metal foam 16 includes applying a protective layer 28 to its peripheral portion to obtain a smooth, non-aggressive peripheral portion. As mentioned before, the protective layer 28 is made of, for example, metal, ceramic or magnesium oxide MgO. When the protective layer 28 is made of metal, it is made of a first liquid metal, for example.

Application of the protective layer 28 may be accomplished by a spraying or painting operation.

Next, the manufacturing method includes assembling the heating apparatus 10.

The heating element 16 is assembled with the insulating element 26 fitted on its outer periphery, and the welding area 24 is exposed.

One retaining element 20 is welded to the housing 12 by welding the fastening tab 30 thereof via the welding hole 32. Next, the heating element 16 provided with the insulating element 26 may be inserted into the housing 12 while being supported by the holding element 20 welded to the inside of the housing 12. During such insertion, the welding zone 24 of the heating element 16 must be arranged opposite the corresponding passage opening 34.

Another holding element 20 may be attached above the heating element 16, the heating element 16 thus being clamped between the two holding elements 20. This further holding element 20 is then welded to the housing 12, like the previously described holding element 20.

Next, the electrodes 22 are each attached through the corresponding passage opening 34, and the conductive core 22a of each electrode 22 is welded to the corresponding welding region 24. This is achieved by the weld region 24 having sufficient density to allow direct contact between the electrode 22 and the metal foam 16.

Next, the outer cover 22c of each electrode 22 is welded to the rim 36 of the passage opening 34 to hold the electrode 22 well to the housing 12.

It should be noted that the present invention allows for good control of the structure of the metal foam, with its size, pore density and uniformity being related to the preform 16 a. Because of its uniformity, all cells have substantially the same shape and the same dimensions, and the thermal constraints are substantially the same throughout the volume of the metal foam 16. Furthermore, the thickness of the metal foam 16 considered in the direction of the longitudinal axis X is preferably constant. In one variant, the thickness of the metal foam 16 is not constant and may, for example, have a local thickening and/or a thickness reduction.

The dimensions and properties of the metal foam 16 are predictable and reproducible, and therefore can be readily simulated and tested to control the mechanical resistance and electrical resistance of the metal foam.

It should be noted that the present invention can also be used to manufacture heating elements 16 having various shapes, in particular having an S-shaped or E-shaped bottom, by selecting preforms 16a having an appropriate shape.

Fig. 5 shows a heating device 10 according to a second exemplary embodiment of the present invention. In this figure, similar elements to those in the two previous figures are indicated with the same reference numerals.

According to this second embodiment, the heating device 10 comprises a first annular retaining element 20 and a second annular retaining element 40 having different shapes.

The first annular retaining element 20 is identical to the retaining element of the first embodiment. It comprises in the same way a fastening tab 30.

In contrast, the second annular retaining element 40 does not comprise a fastening tab but rather an outer peripheral edge 42, with a notch 44 for the passage of the electrode 22. The peripheral edge 42 extends parallel to the longitudinal direction.

The peripheral edge 42 is welded to the housing 12 via the welding holes 32 opposite the peripheral edge 42.

It should be noted that the peripheral edge 42 is preferably oriented to surround the heating element 16.

The second annular retaining element 40 also includes an annular portion 46 that has a sufficient amount of extension in the radial direction to extend across a portion of the heating element 16. The holding elements 20, 40 thus clamp the heating element 16 on both sides of the heating element 16 in the direction of the longitudinal axis X.

This second embodiment has the advantage that the height of the housing 12 in the direction of the longitudinal axis X can be reduced, in particular because the peripheral edge 42 surrounds the heating element 16. Thus, such a height of the housing 12 is for example 51mm and in the first embodiment 65mm, which means that the height is reduced by 14mm in the example described.

Furthermore, the distance between the two circumferential rows of welding holes 32 in the direction of the longitudinal axis X is also reduced relative to the first embodiment.

Overall, the second embodiment makes the form of the heating device 10 more compact.

The present invention is not limited to the above-described embodiments, and various supplementary modifications may be adopted.