EP2136910A1 - Two-stage reformer and method for operating a reformer - Google Patents

Abstract

The invention relates to a reformer (10; 100) for converting fuel and oxidant to reformate (26; 126), comprising an oxidation zone (20; 120), to which a mixture of fuel and oxidant can be supplied via a first fuel supply (12; 112) and a first oxidant supply (16; 116), and, downstream of the oxidation zone (20; 120), an injection and mixture forming zone (22; 122) to which additional fuel can be supplied via a second fuel supply (14; 114), characterized in that a second oxidant supply (18; 118) is provided via which additional oxidant can be supplied to the injection and mixture forming zone (22; 122). According to the invention, the second oxidant supply (18; 118) is arranged with respect to the second fuel supply (14; 114) in such a way that it produces an oxidant buffer in the region upstream of the second fuel supply (14; 114) in order to reduce heat transfer from the mixture in the oxidation zone (20; 120) to the second fuel supply (14; 114). The invention also relates to a method for operating such a reformer (10; 100).

Description

Two-stage reformer and procedure for running a reformer

The invention relates to a reformer for converting

Fuel and oxidant reformate, with an oxidation tion zone, which is supplied via a first BrennstoffZuführung and a first Oxidantmittelzuführung a mixture of fuel and oxidant, and with an oxidation zone downstream injection and mixture forming zone, which is supplied via a second fuel supply further fuel , wherein a second oxidant supply is provided, via which the injection and mixture-forming zone further oxidizing agent can be fed.

Furthermore, the invention relates to a method for operating such a reformer.

Generic reformers are often used in conjunction with operation of a fuel cell or fuel cell stack to generate and supply a hydrogen-rich gas mixture, the reformate, to the fuel cell or fuel cell stack. On the basis of electrochemical processes, the fuel cell can generate electrical energy by supplying this hydrogen-rich gas. Such fuel cells are used for example in the automotive sector as additional energy sources, so-called APUs ("Auxiliary Power Unit") r its application. The reforming process of the reformer for converting fuel and oxidant to reformate can be done according to different principles. For example, catalytic reforming is known in which part of the fuel is oxidized in an exothermic reaction. Furthermore, the so-called "steam reforming" for the production of tion of a reformate from hydrocarbons known. In this case, hydrocarbons are converted by means of water vapor in an endothermic reaction to hydrogen. A combination of both of the above principles, that is, reforming based on an exothermic reaction and generation of hydrogen by an endothermic reaction in which the energy for steam reforming is derived from the combustion of the hydrocarbons, is referred to as autothermal reforming.

A generic, the autothermal Reformierungsart exporting reformer is known for example from DE 103 59 205 Al. This prior art reformer has two fuel feeds and two oxidant feeds, one for both the oxidizer zone and the injection and mixture forming zones. As a result, a clear homogenization of the temperature profile in the reformer and thus an improvement of the reformer behavior is achieved. Thus, in this known reformer, fuel and oxidant, which is usually air, are first fed to the oxidation zone of the reformer, in which part of the fuel is completely oxidized by the oxidant. The oxidation produces a gaseous oxidation product, which is referred to below as so-called flue gas. This flue gas then passes into the injection zone of the reformer downstream of the oxidation zone in which further fuel is supplied again via a second fuel feed. Thus, in the injection and mixture formation zone, a further fuel evaporation takes place, so that the necessary for reforming bottom stoichiometric fuel / air ratio sets in the present mixture. This mixture is then subjected to a reforming zone which, for example, at least partially can be formed by a catalyst of the reformer supplied. According to DE 103 59 205 A1, a second oxidant supply is also provided, via which further oxidizing agent can be fed into the injection and mixture-forming zone. This second oxidant supply serves to optimize the reforming process and represents another parameter influencing the reforming process. However, this reformer according to DE 103 59 205 A1 has the disadvantage that due to the hot flue gas in the injection and mixture-forming zone, a considerable amount of heat is transferred to the second BrennstoffZuführung, in particular on an evaporator fleece of the second fuel supply, is transmitted. As a result of this heat transfer, at least partial pre-evaporations of the fuel to be supplied occur in the second fuel feed or a feed line to the second fuel feed. This pre-evaporation leads to uncontrolled formation of bubbles in the fuel, whereby an uneven, pulsating fuel supply can be caused by the second fuel supply. This uneven

Fuel supply through the second fuel supply in turn leads to an unstable behavior of the reformer, strong temperature fluctuations and a pressure increase due to an increased soot formation within the reformer.

The invention is therefore based on the object of developing the generic reformer and method for operating such reformer so that a Reformierungspro- zessführung in multi-stage reformers can be made more stable.

The reformer according to the invention builds on the generic state of the art in that the second oxidant supply is so in relation to the second fuel supply. is arranged to generate a Sperroxidationsmittel- cushion in the region before the second fuel supply in order to reduce heat transfer from the mixture from the O xidationszone on the second fuel supply. Based on the first and second Oxidationsmittelzufüh- tion of the oxidizing agent is stepped, in this case in two stages, fed to the corresponding zones of the reformer. Preferably, 80% to 90% of the total amount of oxidizing agent required is supplied to the oxidation zone via the first oxidant feed. This ensures a sufficient lambda or a sufficient air ratio of, for example, greater than 1.2. The remaining amount of oxidant, that is, 10% to 20% of the total amount of oxidant, is supplied in the injection and mixture forming zone via the second oxidant feed. In this case, the second oxidant feed with respect to the second fuel feed is designed so that the Sperroxidationsmittel- pad formed of cold oxidizing agent before the second fuel feed in the injection and mixture forming zone and thereby at least reduced heat transfer to the second fuel supply by flue gas. This further reduces a heat conduction within the second fuel supply. Therefore, can be dispensed with an external and separate cooling device for cooling the second fuel supply, which is why no additional cooling power is obtained. By means of the low air ratio or the low lambda in the flue gas or in the mixture from the oxidation zone, cooling of a reforming zone, for example of a catalyst forming the reforming zone, can be counteracted by means of higher temperatures in a flue gas stream, for example by virtue of the heat transfer between the flue gas in the oxidation zone and - -

the reforming zone forming catalyst improved over a wall.

The reformer according to the invention can advantageously be further developed so that the further oxidizing agent at least partially comes into contact with the second fuel feed before it mixes with the mixture from the oxidation zone. This is achieved for example by the special arrangement of the second oxidant supply to the second fuel supply. In particular, it can be provided that the second oxidant supply is designed as a tube surrounding the second fuel feed.

Furthermore, the reformer according to the invention can be designed such that the second fuel feed comprises an evaporator fleece, which is flowed through by the fuel to be supplied to the injection and mixture forming zone. For example, the second fuel supply may be at least partially tubular, wherein the evaporator fleece is inserted into the tubular second fuel feed.

In addition, the reformer according to the invention can be designed so that the second oxidant feed to the second fuel feed is in such heat-transferring relationship that the additional fuel to be supplied via the second fuel feed is already active before entering the injection and mixture forming zone through the second oxidant feed is cooled. This active cooling may be provided in addition to the cooling of the second fuel supply to prevent a pre-evaporation of the other fuel as far as possible. In a preferred embodiment, the reformer according to the invention can be developed such that the first and second oxidant supply are coupled to a common oxidant supply line via which the first and second oxidant feeds are supplied with oxidizing agent. This allows simplification of the two-stage oxidant feed to the reformer. For example, in this case, only a fan may be provided which supplies air as an oxidizing agent and provides both oxidant supply.

Furthermore, the reformer according to the invention can be realized in this context in such a way that a respective oxidant volume flow to the first and second oxidant supply can be set via a volumetric flow divider valve provided on the common oxidant line. Thus, it is possible to divide a total amount of oxidizing agent into a volume flow to the first oxidant supply and to the second oxidant feed. By a variable control of the volume flow divider valve, a targeted adjustment of the temperature level before the second fuel supply depending on the corresponding operating state of the reformer can be done. Furthermore, in the case of air as the oxidizing agent, a variable air ratio between the first oxidation feed and the second oxidation feed can be set in a targeted manner by the supply of oxidant via the volume flow divider valve, without the need for an additional blower.

The inventive method is based on the generic state of the art in that the second oxidant supply in the oxidant supply a Sperroxidationsmittelpolster generated in the region before the second fuel supply to reduce heat transfer from the mixture of the oxidation zone to the second fuel supply. This results in the advantages explained in connection with the reformer according to the invention in the same or similar manner, which is why reference is made to avoid repetition to the corresponding statements in connection with the reformer of the invention.

The same applies mutatis mutandis to the following preferred embodiments of the method according to the invention, wherein reference is made to avoid repetition in this regard to the corresponding statements in connection with the reformer of the invention.

The method according to the invention can advantageously be further developed such that the further oxidizing agent at least partially comes into contact with the second fuel feed before it mixes with the mixture from the oxidation zone.

Furthermore, the inventive method can be realized so that an evaporator fleece of the second fuel supply of the injection and

Mixture forming zone to be supplied with additional fuel is flowed through.

Furthermore, the method according to the invention can be realized in such a way that the additional fuel to be supplied via the second fuel feed is actively cooled by the second oxidant feed before it enters the injection and mixture-forming zone. In a preferred embodiment of the method according to the invention, provision is made for the first and second oxidant supply to be supplied with oxidant by a common oxidation agent line.

In this connection, the method according to the invention can be developed such that a respective oxidant volume flow to the first and second oxidant feed is set via a volume flow divider valve provided on the common oxidant line.

The invention is based on the finding that, in connection with multi-stage, in particular two-stage, reformers, a pulsating fuel feed through a second fuel feed can be prevented by cooling this second fuel feed. On the one hand, this can be achieved by generating a barrier oxidant cushion on the basis of the second oxidant feed, which is specially aligned with the second fuel feed. Alternatively or additionally, active cooling of the second fuel feed can also be carried out, for example by the second oxidant feed; In this case, the second oxidant supply may be disposed adjacent to, in heat transferring relation to the second fuel supply. Both cooling concepts can be realized both in combination and individually.

The invention will now be described with reference to the accompanying drawings

Drawings exemplified with reference to preferred embodiments.

Show it: _ _q _

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Figure 1 is a schematic representation of the reformer according to the invention according to a first embodiment of the invention, which is suitable for carrying out the inventive method; and

Figure 2 is a schematic representation of the reformer according to the invention according to a second embodiment of the invention, which is suitable for carrying out the inventive method.

Figure 1 shows a schematic representation of a reformer 10 according to the invention according to a first embodiment of the invention, which is suitable for carrying out the method according to the invention. The reformer 10 according to the invention comprises an oxidation zone 20, which can be supplied with fuel and oxidant via a first fuel feed 12 and a first oxidant feed 16. As fuel, for example, natural gas, diesel or gasoline in question, the oxidizing agent is usually

Air. The supply of the fuel and the oxidizing agent results in a mixture which flows into the oxidation zone 20 and at least partially oxidizes there, so that a flue gas can be formed in the oxidation zone 20. In the oxidation zone 20 thus finds a reaction of

Fuel and oxidant in an exothermic reaction with an air ratio of 1 (λ ~ 1) instead. Subsequently, the mixture or flue gas flows or flows into an injection and mixture formation zone 22 downstream of the oxidation zone 20. In the injection and mixture formation zone 22, a second fuel feed 14 and a second oxidant feed 18 are provided, each injecting further fuel and further oxidant into the injection chamber. and mixture forming zone 22 feed. The thermal energy of the flue gas originating from the oxidation zone 20 can thereby contribute to the vaporization of the further fuel of the second fuel feed 14. However, in order to keep heat transfer to the second fuel feed 14 as small as possible by the flue gas, the second oxidant feed 18 is arranged in such a way that a barrier oxidant cushion is produced in the region in front of the second fuel feed 14 in the case of an oxidant feed. As a result, heat transfer from the mixture of the oxidation zone 20 or the flue gas to the second fuel feed 14 is reduced. In particular, it is provided in this exemplary embodiment that the oxidant supplied by the second oxidant supply 18 at least partially makes contact with the second fuel feed before it mixes with the mixture or flue gas from the oxidation zone 20. In addition, active cooling of the second fuel supply 14 may be performed by the second oxidant supply 18 by having the second fuel supply 14 in a heat transferring relationship with the second oxidant supply 18. In particular, the second fuel feed 14 can be formed as a tube, which is arranged concentrically within a pipe forming the second oxidant feed 18. Thus, active cooling of the second fuel feed 14 and the fuel to be supplied thereto already takes place before the further fuel is fed into the injection and mixture-forming zone 22 through the second oxidant feed 18. The gas mixture formed in the injection and mixture-forming zone 22 then passes into a downstream reforming zone which is at least partially formed by a catalyst 24. There, the gas mixture in an endothermic - -

Reaction with, for example, λ ∞ 0.4 converted to reformate 26. Following this, the generated reformate 26 flows out of the catalyst 24 via a reformer outlet. In this case, the reforming zone 24 and the oxidation zone 20 can be formed such that they are in a heat-transferring relationship with one another, so that heat required for the endothermic reaction can be obtained from the oxidation zone 20.

The inventive method for operating the reformer 10 according to the invention is as follows. First, the fuel and the oxidant, in this case air, are supplied through the first fuel feed 12 and the first oxidant feed 16 to the oxidation zone 20. This results in a gas mixture which oxidizes in the oxidation zone 20 at least partially to an oxidized mixture or flue gas. The resulting flue gas then flows from the oxidation zone 20 into the injection and mixture formation zone 22. There, the flue gas is further fuel through the second

Fuel supply 14 is supplied, in addition further oxidizing agent is supplied through the second oxidant supply 18. In this case, the further oxidizing agent of the second oxidant supply 18 is supplied so that the Sperroxidationsmittelpolster formed in the region in front of the second fuel supply 14 to reduce the heat transfer from the mixture or flue gas from the oxidation zone 20 to the second fuel supply 14. Subsequently, the resulting gas mixture passes into the reforming zone forming catalyst 24, in which it is converted to a reformate 26 and is discharged from the reformer 10 via a reformer outlet. Figure 2 shows a schematic representation of a reformer 100 according to the invention according to a second embodiment of the invention. In order to avoid repetition, the description of this exemplary embodiment merely addresses the differences from the first exemplary embodiment, wherein identical or similar components of the second exemplary embodiment are designated by similar reference symbols with regard to components of the first exemplary embodiment. The second exemplary embodiment differs from the first exemplary embodiment in that the first and second oxidant feeders 116 and 118 are coupled to a common oxidant line 130 via a volume flow divider valve 128. The oxidant conduit 130 is in turn coupled to an oxidant supply means for supplying oxidant; in the case of air as an oxidizing agent, the oxidant supply means is formed by a blower. Based on the volume flow diverting valve 128, corresponding volume flows of the first and second oxidant feeds 16 and 18 can be supplied. As a result, only one oxidant supply device is required, which supplies the oxidant to the common oxidant line 130.

The features of the invention disclosed in the foregoing description, in the drawings and in the claims may be essential to the realization of the invention both individually and in any combination. - -

LIST OF REFERENCE NUMBERS

10 reformers

12 first fuel supply 14 second fuel supply

16 first oxidant supply

18 second oxidant supply

20 oxidation zone

22 injection and mixture forming zone 24 catalyst device

26 Reformat

100 reformers

112 first fuel feed

114 second fuel supply 116 first oxidant supply

118 second oxidant supply

120 oxidation zone

122 injection and mixture formation zone

124 Catalyst device 126 Reformat

128 volume flow divider valve

130 oxidizer line

Claims

- -CLAIMS

A reformer (10; 100) for converting fuel and oxidant to reformate (26; 126), comprising an oxidation zone (20; 120) via a first fuel feed (12; 112) and a first oxidant feed (12). 16; 116), and with an injection and mixture-forming zone (22; 122) downstream of the oxidation zone (20; 120), to which further fuel can be fed via a second fuel feed (14; 114) in that a second oxidant supply (18; 118) is provided, via which more oxidizing agent can be supplied to the injection and mixture-forming zone (22; 122), characterized in that the second oxidant supply (18; 118) with respect to the second fuel feed (14; 114) is arranged to generate a barrier oxidant pad upstream of the second fuel supply (14; 114) to transfer heat from the mixture of the oxidation zone e (20; 120) is applied to the second fuel feeder (14; 114).

2. A reformer (10; 100) according to claim 1, characterized in that the further oxidizing agent at least partially in contact with the second fuel supply (14; 114) before it mixes with the mixture of the oxidation zone (20; 120).

3. A reformer (10; 100) according to claim 1 or 2, characterized in that the second fuel feed (14; 114) comprises an evaporator fleece, which of the injection and Flow through the mixture forming zone (22; 122) to be supplied further fuel.

A reformer (10; 100) according to any one of claims 1 to 3, characterized in that the second oxidant supply (18; 118) is in heat transfer relationship with the second fuel supply (14; Additional fuel to be supplied to the second fuel supply (14; 114) is actively cooled by the second oxidant supply (18; 118) even before it enters the injection and mixture formation zone (22; 122).

5. A reformer (100) according to any one of claims 1 to 4, character- ized in that the first and second oxidant feeds (116, 118) are coupled to a common oxidant onsmittelleitung (130) via which the first and second oxidant supply ( 116, 118) are supplied with oxidizing agent.

6. reformer (100) according to any one of claims 5, characterized in that a respective oxidant volume flow to the first and second oxidant supply (116, 118) via a on the common Oxidationsmittellei- device (130) provided volume flow divider valve (128) is adjustable ,

A method of operating a reformer (10; 100) to convert fuel and oxidant to reformate (26; 126), the reformer comprising an oxidation zone (20;

120), to which a mixture of fuel and oxidizing agent can be supplied via a first fuel feed (12; 112) and a first oxidant feed (16; 116), and an injection and a downstream of the oxidation zone (20; 120) - -

Comprising a second oxidant feed line (18; 118) via which the injection and mixture formation zone (22; 122) is provided with a second oxidant feed line (22; 122) which can be supplied with further fuel via a second fuel feed (14; 114). characterized in that the second oxidant supply (18; 118) generates a barrier oxidant cushion in the region upstream of the second fuel feed (14; 114) during the oxidant supply to transfer heat from the mixture from the oxidation zone (20; ) to the second fuel feeder (14; 114).

8. The method according to claim 7, characterized in that the further oxidizing agent at least partially with the second fuel supply (14; 114) comes into contact before it mixes with the mixture of the oxidation zone (20; 120).

9. Method according to claim 7 or 8, characterized in that an evaporator fleece of the second fuel feed (14; 114) is traversed by the further fuel to be supplied to the injection and mixture-forming zone (22;

10. The method according to any one of claims 7 to 9, characterized in that the further fuel to be supplied via the second fuel supply (14; 114) .before entry into the injection and mixture forming zone (22; 122) by the second oxidant supply (18; 118) is actively cooled.

11. The method according to any one of claims 7 to 10, characterized in that the first and second oxidant - -

Supply (116, 118) from a common Oxidationsmit- line (130) are supplied with oxidizing agent.

12. The method according to any one of claims 11, characterized in that a respective oxidant volume flow to the first and second oxidant supply (116, 118) via a on the common oxidant line (130) provided volume flow divider valve (128) is adjusted.