DE102007001375A1 - Method of operating a reformer, reforming system and fuel cell system - Google Patents

Abstract

The invention relates to a method for operating a reformer (10) to produce a hydrogen-rich reformate (20), wherein the reformer fuel (16) and oxidizing agent (18) are supplied. According to the invention, it is provided that at least one property of the fuel (16) supplied to the reformer (10) is determined and that the quantity ratio of supplied fuel (16) and oxidant (18) is set as a function of the at least one property. The invention further relates to a reforming system and a fuel cell system.

Description

The The invention relates to a method for operating a reformer for Producing a hydrogen-rich reformate, wherein the reformer is fuel and oxidizing agent supplied become.

The The invention further relates to a reforming system with a reformer and an electronic control unit, wherein the reformer is fuel and Supplied oxidizing agent become.

Farther The invention relates to a fuel cell system.

reformer serve to produce a hydrogen-rich mixture, which in particular for the generation of electrical energy in a the reformer downstream fuel cell assembly is used. To this Purpose will be the reformer hydrocarbons as fuel and a Supplied oxidizing agent. In particular, atmospheric oxygen is used as the oxidizing agent. The fuels can liquid and gaseous be fed wherein in the mobile field of application, in particular, an internal combustion engine supplied fuels also as fuels for to be used by the reformer.

Out several reasons is it desirable that a reformer with different fuels can be operated. For one thing As a result, identical reformer be used in systems that for different Fuels are designed. On the other hand, in this way the Basis for it created be that one and the same plant with different fuels operated without loss of efficiency can be. In the mobile sector, this is particularly interesting Since there are also internal combustion engines, which different fuels can handle. A motor vehicle equipped with such an internal combustion engine is, therefore, should be possible also have a reformer, the various fuels in appropriate Can implement manner.

Of the Invention is based on the object, methods, systems and systems of the prior art in such a way that suitable reforming processes can take place at varying fuel properties.

These The object is achieved by the features of the independent claims.

advantageous embodiments of the invention are in the dependent claims specified.

The Invention builds on the generic method thereby, that at least one property of the fuel supplied to the reformer is determined and that depending the at least one property, the ratio of fuel supplied and oxidizing agent is adjusted. To the reforming process to optimize, so first determines a property of the fuel supplied to the reformer. Dependent on then the air ratio can be determined from this property, So a size, which a decisive influence on the functioning of the reformer Has. The air ratio is particularly close to the temperature profile in the Coupled with the reformer, so that by a suitable adjustment of the Air ratio desired Temperature profiles and thus an optimized reformer operation for disposal can be made.

For example it can be provided that the at least one property characterizes the fuel type. It can therefore in particular between different fuel gases, diesel and gasoline.

Also can be useful be that the at least one characteristic characterizes the fuel quality. In connection with gasoline, the quality of the fuel is improved the Ok number is indicated. Comparable key figures exist also for other fuel types.

Also may be advantageous that the at least one property the Purity of the fuel features. In particular, diesel will distributed with different purity. This concerns above all Sulfur impurities in diesel that affect the performance of the Reformer and a fuel cell system to which the reformer belongs can. Is that the measure? Sulfur impurities known, so the operating point of the reformer be voted on, in particular with a view to: preferably slight sulfur deposits occur in the reformer.

From It is particularly advantageous that at least two positions in Range of the reformer is a temperature is measured and the temperature information additionally in adjusting the quantity ratio of fuel supplied and oxidizing agents becomes. about The determination of the fuel properties can therefore first the Air ratio in the reformer can be adjusted so that a desired mode of operation of the reformer is to be expected. The setting of these desired Operation can then be supported by the fact that the temperature profile is determined in the reformer. On this basis, corrections can be made at the original adjusted air ratio.

Especially is it useful that the quantity ratio supplied from Fuel and oxidant is adjusted so that the in Range of the reformer measured temperatures as possible have small difference.

The Invention is further developed in a particularly advantageous manner, that the quantity ratio supplied from Fuel and oxidizer based on in an electronic Control unit stored maps is controlled, with different Maps for different Characteristics of the fuel supplied to the reformer are present. A regulation of the air ratio - one so-called lambda control - can on the basis of a specially for this provided lambda probe or by a suitable evaluation of electrical parameters of the reformer downstream fuel cell assembly respectively. Such a regulation based on maps It makes sense to make that since the systematic dependencies between the lambda values and the operating behavior of the reformer hardly are detectable in another way.

The Invention builds on the generic reforming system thereby on, that at least one property of the fuel supplied to the reformer can be determined and detected by the electronic control unit and that in dependence the at least one property, the ratio of fuel supplied and oxidizing agent by the electronic control unit adjustable is. In this way, the advantages and peculiarities of inventive method implemented under a reforming system. This also applies to the following specified particularly preferred embodiments of the system.

This can be developed by the fact that at least one sensor for Capture the fuel quality is provided, wherein the at least one property characterizes the fuel quality.

Also can be provided that at least one sensor for detecting the Purity of the fuel is provided, wherein the at least one Feature that features the purity of the fuel.

The inventive reforming system is more useful Way further developed that at least two temperature sensors provided at least two positions in the region of the reformer are and that the temperature information can be determined in addition the setting of the quantity ratio supplied from Fuel and oxidizer through the electronic control unit considered can be.

In In this context, it is particularly useful that the ratio of supplied Fuel and oxidant so through the electronic control unit it is adjustable that the temperatures measured in the area of the reformer one possible have small difference.

From It is particularly advantageous that the quantitative ratio of fuel supplied and oxidizing agents based on in the electronic Control unit stored maps is adjustable, with different Identification fields for various properties of the fuel supplied to the reformer available.

Of the The invention is based on the finding that by the lambda value adjustment adjusted to the fuel the temperature level in the reformer can be. At a constant supply of oxidant and Fuel will become constant after some time a, in particular with regard to the state variables temperature and pressure. Especially in terms of temperature, a limitation is required so as not to overload the reformer, especially with regard to a catalyst. Due to the fuel-dependent lambda value adjustment can So the position of the thermodynamic equilibrium and thus the Temperature level can be set in the reformer advantageous, wherein in connection with advantageous embodiments of the invention Even on a homogeneous temperature profile can be respected. Typical lambda values are for Gasoline and diesel in the area larger or equal to .35 while Lambda values for Natural gas in the range larger or equal to 0.25 are settled.

The The invention further relates to a fuel cell system with a reforming system according to the invention.

The Invention will now be described with reference to the accompanying drawings particularly preferred embodiments exemplified.

It demonstrate:

1 a schematic representation of a reforming system according to the invention and

2 a flowchart for explaining a method according to the invention.

1 shows a schematic representation of a reforming system according to the invention. The reforming system according to the invention comprises a reformer 10 to which a fuel supply device 12 and an oxidizer feed direction 14 assigned. At the fuel supply device 12 it is generally a pump while the oxidant supply means 14 an air blower is. Through these devices 12 . 14 become the reformer 10 fuel 16 and oxidizing agents 18 fed. After suitable conversion of these substances in the reformer 10 delivers the reformer 10 a hydrogen-rich reformate 20 which can then be supplied in particular to a fuel cell stack for generating electrical energy. The fuel supply device 12 and the oxidant supply device 14 be from an electronic control unit 22 controlled. When integrating the reforming system in a fuel cell system, the electronic control unit 22 also control or regulate other functions of the fuel cell system. To capture a property of the reformer 10 supplied fuel 16 is a sensor in the fuel supply line 24 provided, the output signal of the electronic control unit 22 is supplied. Furthermore, in the reformer 10 two temperature sensors 26 . 28 arranged, the information obtained also to the e lectronic control unit 22 deliver. When commissioning the reforming system can thus first by the sensor 24 a property of the supplied fuel can be determined, for example the type of fuel, the quality of the fuel and / or the purity of the fuel. On this basis, then the air ratio can be adjusted, in particular by influencing the fuel supply 12 and / or the Oxidantmittelzuführeinrichtung 14 , For fine adjustment of the air ratio, that is to say in particular for providing a desired value for a lambda control, it is then possible for the temperature sensors to be used 26 . 28 determined temperatures are taken into account. For example, it is desirable that in the reformer 10 If the temperature profile is as constant as possible, the air ratio can be varied until the difference between the temperatures of the temperature sensors 26 . 28 determined temperatures is as low as possible with further consideration of the absolute temperature.

2 shows a flowchart for explaining a method according to the invention. After the start of the reformer in step S01, the fuel type is detected in step S02. The detection of the fuel type is used here by way of example to explain the method according to the invention. It is therefore determined whether a motor vehicle is fueled, for example, with diesel or gasoline. In step S03, the air ratio is then set as a function of the determined type of fuel. This process may imply that only the fuel pump and / or the air blower are adjusted so that a certain air ratio is expected. However, the setting of the air ratio may further implies that a desired value is provided for a lambda control, that is to say a fuel-type-dependent desired value, whereby a lambda control known per se can then take place on this basis. In a step S04, the temperature profile in the reformer is then determined, for example by detecting two temperatures at different positions. If it is subsequently determined in step S05 that the temperature profile is still unacceptable, the air ratio is varied in step S06. Following this, the temperature profile is again determined in step S04. If it is determined in step S05 that an acceptable temperature profile is present, then in step S07 the reforming system is converted into its continuous operation. The presence of this continuous operation does not exclude that there is a permanent detection of the fuel type. This has the background that even during a progressive reformer operation, a change of the fuel can take place, for example, when a motor vehicle is refueled. Here too, it is thus possible to react if continuous testing of the fuel type takes place in the context of continuous operation, in particular in connection with a determination of the temperature profile in the reformer.

The in the above description, in the drawings and in the claims disclosed features of the invention can both individually and also in any combination for the realization of the invention be essential.

10

reformer

12

fuel supply

14

oxidant feeder

16

fuel

18

oxidant

20

reformate

22

control unit

24

sensor

26

temperature sensor

28

temperature sensor

Claims (15)

Method for operating a reformer ( 10 ) for producing a hydrogen-rich reformate ( 20 ), whereby the reformer receives fuel ( 16 ) and oxidizing agents ( 18 ), characterized in that at least one property of the reformer ( 10 ) supplied fuel ( 16 ) and that, depending on the at least one property, the quantity ratio of fuel supplied ( 16 ) and oxidizing agents ( 18 ) is set. A method according to claim 1, characterized in that the at least one property the Fuel type features. Method according to claim 1 or 2, characterized that the at least one characteristic characterizes the fuel quality. Method according to one of the preceding claims, characterized characterized in that the at least one property is purity of fuel. Method according to one of the preceding claims, characterized characterized in that at least two positions in the range of Reformers a temperature is measured and the temperature information additionally in adjusting the quantity ratio of fuel supplied and oxidizing agents becomes. Method according to claim 5, characterized in that that the quantity ratio supplied from Fuel and oxidant is adjusted so that the in Range of the reformer measured temperatures as possible have small difference. Method according to one of the preceding claims, characterized in that the quantity ratio of supplied fuel and oxidant based on in an electronic control unit ( 22 ) are stored, with different maps for different properties of the reformer supplied fuel. Reforming system with a reformer ( 10 ) and an electronic control unit ( 22 ), whereby the reformer receives fuel ( 16 ) and oxidizing agents ( 18 ), characterized in that at least one property of the reformer ( 10 ) supplied fuel ( 16 ) and by the electronic control unit ( 22 ) is detectable and that, depending on the at least one property, the quantity ratio of fuel supplied ( 16 ) and oxidizing agents ( 18 ) is adjustable by the electronic control unit. Reforming system according to claim 8, characterized in that at least one sensor ( 24 ) is provided for detecting the fuel type, wherein the at least one characteristic characterizes the fuel type. Reforming system according to claim 8 or 9, characterized in that at least one sensor ( 24 ) is provided for detecting the fuel quality, wherein the at least one characteristic characterizes the fuel quality. Reforming system according to one of claims 8 to 10, characterized in that at least one sensor ( 24 ) is provided for detecting the purity of the fuel, wherein the at least one property characterizes the purity of the fuel. Reforming system according to one of claims 8 to 11, characterized in that at least two temperature sensors ( 26 . 28 ) in at least two positions in the area of the reformer ( 10 ) are provided and that the thus determined temperature information in addition in the adjustment of the quantity ratio of fuel supplied ( 16 ) and oxidizing agents ( 18 ) by the electronic control unit ( 22 ) can be taken into account. Reforming system according to claim 12, characterized in that the quantity ratio of supplied fuel ( 16 ) and oxidizing agents ( 18 ) so by the electronic control unit ( 22 ) that is adjustable in the area of the reformer ( 10 ) measured temperatures have the smallest possible difference. Reforming system according to one of claims 8 to 13, characterized in that the quantity ratio of fuel supplied ( 16 ) and oxidizing agents ( 18 ) based on in the electronic control unit ( 22 ) is variable, with different maps for different properties of the reformer ( 10 ) supplied fuel ( 16 ) are present. Fuel cell system with a reforming system according to one of the claims 8 to 14.