DE10240953A1 - Device for producing hydrogen has conversion stages and fine purification stage formed as hollow bodies having an annular chamber for receiving corresponding catalysts - Google Patents

Abstract

Hydrogen production device comprises heated steam reforming stage with reforming catalyst to convert gaseous hydrocarbons and water into hydrogen, carbon monoxide and further reformer products, conversion stages to catalytically convert hydrogen, carbon monoxide and steam mixture leaving reforming stage, and fine purification stage to catalytically reduce residual carbon monoxide in conversion products. Device for producing hydrogen comprises heated steam reforming stage (1) with reforming catalyst to convert gaseous or vaporizable hydrocarbons and water into hydrogen, carbon monoxide and further reformer products, conversion stages (2a, 2b) connected to reforming stage to catalytically convert mixture of hydrogen, carbon monoxide and excess steam leaving reforming stage, and fine purification stage (3) connected to conversion stages to catalytically reduce residual carbon monoxide content of conversion products. Conversion stages and purification stage are each formed as hollow bodies having annular chamber for receiving corresponding catalysts.

Description

The invention relates to an apparatus for the production of hydrogen according to the preamble of the claim 1.

A generic apparatus is, for example, from the (not yet published) DE 102 13 326.3 known. With this apparatus, hydrogen is preferably generated for the operation of a polymer membrane fuel cell, the entire gas generation and fuel cell system being usable as a domestic energy supply system for generating electricity and heat.

In this apparatus, the at least one the catalyst stage downstream of the reformer is essentially one hollow cylindrical shape, which has the advantage that the radial, temperature distribution much more even than is formed in a cylindrical catalyst stage. The temperature distribution is therefore for the reform process of particular importance as it is immediate Influence on the equilibrium reaction in the conversion of carbon dioxide in carbon monoxide. For example, consider one usually used cylindrical shift stage, so lead radially different Temperatures at different carbon monoxide proportions in the product gas, what, because the use of the catalyst stages on a possible low carbon monoxide content in the product gas, no optimal results has the consequence.

With the use of the hollow cylindrical catalyst stage after the DE 102 13 326.3 the problem of radially uneven temperature distribution is essentially solved. In addition, it has also proven to be problematic that within the catalyst stage in the axial direction, due to the exothermic reaction during the conversion of carbon dioxide to carbon monoxide, the temperature profile also becomes uneven and thus the gas quality deteriorates.

The invention is accordingly based on the object in the case of an apparatus of the type mentioned at the beginning, if possible simple technical means, an equalization of the temperature profile to realize in the axial direction of the catalyst stage.

This task is with an apparatus of the type mentioned in the characterizing part of the claim 1 mentioned features solved.

According to the invention it is therefore provided to provide the at least one shift stage with an enclosure, through which a cooling medium promoted is used to converting carbon dioxide to carbon monoxide to remove the heat generated. How later still detailed is described, on the one hand, form the surface of the Shift stage catalyst (or a corresponding casing) and on the other hand, the wall of the enclosure housing the flanks of the cooling duct according to the invention, which also has the advantage that those in the Shift level heat deliberately dissipated can be released and not useless to the environment of the apparatus becomes. Due to the outer jacket cooling results a considerable equalization of the axial temperature profile, d. H. through the combination of outer jacket cooling and Training of the catalyst as a hollow cylinder is at every point the shift level to the same extent Carbon dioxide converted to carbon monoxide.

After an advantageous further education it is provided that the flow guide housing and drain connections for the cooling medium has and optionally in cocurrent or countercurrent to the flow direction is designed to flow through within the catalyst stage. Is in on the reaction side at the catalyst inlet with a strong heat generation to count, favors DC operation due to the larger thermodynamic temperature difference the cooling effect of the media involved and thus an operation in the direction of isometry, d. H. towards one even temperature distribution in the shift stage. The same applies to the reverse case of Counter current.

Furthermore, what is described in more detail is provided that optionally for preheating the reformer supplied Water and / or hydrocarbon gas this or this as the cooling medium Flow guide housing can be fed or are, for which purpose the flow guide housing is preferred on the discharge connection side hydraulically with the educt input of the reformer connected is.

Another advantageous training of the apparatus according to the invention consists in the fact that optionally at the inlet and / or outlet connections of the Flow guide housing Control valve for mass flow adjustment of the cooling medium is provided. Together with one after the at least one catalyst stage in the flow path of hydrogen and the rest Reformer products arranged temperature sensor and a parent The control device is at the catalyst stage outlet temperature oriented mass flow setting of the cooling medium, which, as I said, can also be formed from the reformer starting materials, possible.

Other advantageous developments result from the dependent Claims.

The apparatus of the invention and its advantageous Developments according to the dependent claims in the following with the aid of the drawing of an embodiment explained in more detail.

It shows schematically

1 on average the apparatus according to the invention with a flow guide housing for cooling the outer casing of the shift stage; and

2 a section through the apparatus according to 1 along the line AA.

In 1 the apparatus for generating hydrogen according to the invention is shown in a longitudinal section. This apparatus includes a reformer 1 for converting hydrocarbon gas (preferably natural gas) and water into hydrogen and other reformer products such as carbon dioxide and carbon monoxide. In the illustrated embodiment, the reformer 1 formed as a hollow cylindrical body, in the free center of which a gas burner (preferably a so-called radiation burner) 10 is arranged to generate the heat required for the reforming. The reformer 1 is a hollow cylindrical catalyst stage to reduce the carbon monoxide content (there could also be several - high-temperature and low-temperature shift stage, as well as SelOx or methanation stage) 2 downstream. “Hollow cylindrical” is of course also to be understood to mean, for example, polygonal hollow bodies which are designed to be thin-walled to ensure a uniform temperature profile. Hydrogen production is thus carried out according to the following steps: First, hydrocarbon gas and water vapor are fed to the reformer, where they are converted into hydrogen, carbon dioxide and carbon monoxide using the heat of the gas burner (temperature about 800 ° C.). At the reformer outlet, the product gas is generated by means of a heat exchanger located there 13 cooled to a temperature suitable for the catalytic process to reduce the carbon monoxide content. In the catalyst stage 2 the carbon dioxide is then converted into carbon monoxide at a temperature level of approximately 250 ° C. to 300 ° C. After the shift stage, which, as mentioned, depending on the required purity of the product gas, further, possibly also hollow cylindrical stages, such as, for example, methanation or SelOx stage, can follow, the essentially carbon monoxide-free gas passes through the product gas line 12 to the fuel cell.

For the apparatus according to the invention, the axial temperature profile is now made uniform within the catalyst stage 2 essential that a flow guide housing enclosing this from the outside 3 for a cooling medium for cooling the catalyst stage 2 is provided. How especially out 2 can be seen in the illustrated embodiment, this flow guide housing 3 sort of like the catalyst stage 2 enclosing cylindrical jacket formed, which delimits a concentric annular gap through which the cooling medium flows. Of course, other designs of the housing can also be implemented: it is essential that sufficient heat dissipation from the outer periphery of the catalyst stage is ensured. For this purpose, for example, even a coiled tubing enclosing the catalyst stage is suitable, which, in general terms, is nothing other than the claimed flow guide housing 3 is.

As continues in 1 shown, it is provided in this preferred embodiment that the flow guide housing 3 Supply and drain connections 5 for the cooling medium and from the coolant in countercurrent to the flow direction within the catalyst stage 2 is designed to flow through. As the cooling medium, the water that is required for the reformer process is preferably used, which is due to the flow guide housing according to the invention 3 advantageously comes preheated to the reformer entrance. If necessary, however, the hydrocarbon gas required for the reformer process can also be supplied together with the water via the supply connection 4 the flow guide housing 3 fed and preheated there.

For setting the mass flow of the cooling medium, it is preferably in the exemplary embodiment shown at the supply connection 4 a control valve 6 provided that via a line with a higher-level control device 8th communicates. At the same time is preferably after the catalyst stage 2 A temperature sensor in the flow path of the hydrogen and the other reformer products 7 is arranged, which in turn for mass flow adjustment of the cooling medium via the higher-level control device 8th with the control valve 6 connected is. In this way, depending on the product gas outlet temperature, the cooling capacity on the outer surface of the catalyst stage 2 can be varied within certain limits.

Finally, it is advantageously provided that inside the hollow cylindrical catalyst stage 2 another cooling medium channel 9 is arranged, through which water and / or hydrocarbon gas can flow, preferably. The cooling medium is supplied via the connection line 11 ; the discharge line is not shown since it is easily conceivable.

1

reformer

2

catalyst stage

3

Flow guidance housing

4

supply port

5

withdrawal connection

6

control valve

7

temperature sensor

8th

control device

9

Coolant channel

10

gas burner

11

connecting cable

12

Product gas line

13

heat exchangers

Claims (8)

Apparatus for generating hydrogen in order capturing a reformer ( 1 ) for converting hydrocarbon gas and water into hydrogen and other reformer products such as carbon dioxide and carbon monoxide, the reformer ( 1 ) to reduce the carbon monoxide content at least one hollow cylindrical catalyst stage ( 2 ) is connected downstream, characterized in that the catalyst stage ( 2 ) surrounding flow guide housing ( 3 ) for a cooling medium for cooling the catalyst stage ( 2 ) is provided. Apparatus according to claim 1, characterized in that the flow guide housing ( 3 ) To- ( 4 ) and drain connections ( 5 ) for the cooling medium and optionally in cocurrent or countercurrent to the direction of flow within the catalyst stage ( 2 ) is designed to flow through. Apparatus according to claim 1 or 2, characterized in that for preheating the reformer ( 1 ) water supplied to the flow guide housing as a cooling medium ( 3 ) can be fed. Apparatus according to one of Claims 1 to 3, characterized in that for preheating the reformer ( 1 ) supplied hydrocarbon gas this as a cooling medium to the flow guide housing ( 3 ) can be fed. Apparatus according to one of claims 2 to 4, characterized in that the flow guide housing ( 3 ) hydraulically with the reformer on the discharge connection side ( 1 ) is connected on the educt input side. Apparatus according to one of claims 2 to 5, characterized in that optionally at the inlet (4) and / or outlet connections ( 5 ) of the flow guide housing ( 3 ) a control valve ( 6 ) is provided for setting the mass flow of the cooling medium. Apparatus according to claim 6, characterized in that after the at least one catalyst stage ( 2 ) a temperature sensor in the flow path of the hydrogen and the other reformer products ( 7 ) is arranged, which is used to set the mass flow of the cooling medium via a higher-level control device ( 8th ) with the control valve ( 6 ) connected is. Apparatus according to one of claims 1 to 7, characterized in that in the interior of the hollow cylindrical catalyst stage ( 2 ) another cooling medium channel ( 9 ) is arranged, which can be flowed through and preferably by water and / or by hydrocarbon gas.