WO2011012507A1

WO2011012507A1 - Method and device for generating hydrogen and oxygen

Info

Publication number: WO2011012507A1
Application number: PCT/EP2010/060520
Authority: WO
Inventors: Alexander Hahn; Wolfgang Schilling; Werner Straub; Manfred Waidhas
Original assignee: Siemens Aktiengesellschaft
Priority date: 2009-07-31
Filing date: 2010-07-21
Publication date: 2011-02-03
Also published as: EP2459773A1; DE102009035440A1; US20120125779A1

Abstract

The generation of gases using electrolysis is known, wherein in the prior art the electrical energy therefor is taken from the grid. According to the invention, the electrolysis occurs as a high-pressure electrolyzer, oxygen being produced on one side and hydrogen on the other side, with corresponding pressure. Said gases may optionally be stored without additional compression. The PEM fuel cell process is used in reverse for the process. It is advantageous that excess energy may be used by wind power plants. In the associated device, a high-pressure electrolyzer (1) is present which is operated using environmentally friendly air power. Due to the improved operating point of the high-pressure electrolyzer, improved economy results for the generation process compared to the prior art, in particular for hydrogen as an energy storage means.

Description

description

Method and device for generating hydrogen and oxygen

The invention relates to a process for the production of hydrogen and oxygen, in particular, the excess energy from wind turbines to be used. In addition, the invention also relates to an associated apparatus for performing the method, in which a PEM fuel cell is used as an electrolyzer.

By reversing the fuel cell process, a

Fuel cell can be used for the production of hydrogen on the one hand and oxygen on the other hand. The fuel cell then works as an electrolyzer and must be supplied with electrical power. For example, the electric power of wind turbines comes into question. In wind turbines, the electrical power generated is used as wind energy directly on site to generate electricity. In the absence of wind energy other power plants have to replace the wind turbine. If the installed wind power is increased, the system must be shut down or the energy dissipated by a long-range distribution in case of excess generation. Both reduce the degree of utilization of the system.

The electrolysis devices used hitherto for the production of hydrogen on the one hand and oxygen on the other hand are devices which generally operate at atmospheric pressure. An application of such devices is z. B. the use of hydrogen as corrosion protection in pipe systems in the restricted area of nuclear power plants.

The object of the invention, in contrast, is to propose a method and to provide the associated device with which, in particular, hydrogen is used as the process gas with high energy. can be generated content, wherein the hydrogen can serve as energy storage on the one hand or as synthesis gas for other industrial plants. In particular, the surplus energy of wind turbines, which is not polluted by CO2, should be used.

The object is achieved by the sequence of process steps according to claim 1. An associated device is specified in claim 11. Further developments of the method according to the invention or of the associated device are the subject matter of the dependent claims.

With the invention can be used in a simple manner resulting from wind turbines excess energy. This excess energy is stored in particular in the form of hydrogen, whereby the storage becomes comparatively easy by the use of a high-pressure electrolyzer. In particular, the PEM high-pressure electrolysis in question, in which pressures greater than 10 bar can be realized. In the associated device, the filling of gas storage by means of suitable devices and compressor is much easier and can even be dispensed with, decisive advantage of a high-pressure cell used as a device is that with increasing process pressure, the cell can be operated with higher current densities. This has been tested in practice, especially for PEM high-pressure cells.

Within the scope of the invention, the use of the known high pressure electrolysis, i. Specifically, the water circuit, the electrolysis cell and the gas separation realized such that the facilities were designed as a pressure vessel. This advantageously an operating pressure of up to 110 bar was possible. However, constructive measures increase the operating pressure even further.

An advantage of the described high-pressure electrolysis system according to the invention is the direct generation of the high gas pressure ckes without additional compressors. Alternatively, the high pressure electrolysis may precompress the gas only to subsequently compress the pressure by compressors in a simple and inexpensive manner. Since the amount of gas generated depends directly on the adjustable current density, the possibility of being able to set higher current densities with increasing pressures is another advantage of the high-pressure system. The use of surplus electricity makes the use of the

Electrolysis for the production of particular hydrogen particularly useful. The otherwise unused power can now be used to generate gas and the produced gas can be z. B. chemical industry o. The like. continue to be sold.

Overall, the PEM electrolysis offers the advantage that it can be operated highly dynamically, which is not possible with the other electrolysis systems. The latter must be run at great expense in each case to achieve reasonably steady operating conditions.

Further details and advantages of the invention will become apparent from the following description of exemplary embodiments in conjunction with the claims.

Show it

Figure 1 is a block diagram of a high-pressure electrolysis plant with gas cleaning and the associated storage tanks and

Figure 2 is a graph of the operating voltage of a cell used in Figure 1 as a function of the current density. In FIG. 1, 1 denotes a so-called high-pressure electrolyzer. Such a high-pressure electrolyzer realizes a water electrolysis by applying a voltage to the Electrodes and supplies as a result, on the one hand gaseous oxygen and on the other hand gaseous hydrogen.

The electrolysis takes place by applying an electrical voltage to the corresponding fuel cell and thus realizes an energy converter. That electrical energy output is converted into a process gas as energy storage. Conversely, an electrolyzer can also be used for the generation of electrical energy power, in which case can be spoken of a fuel cell.

In the case of the so-called PEM fuel cell (polymer electrolyte membrane), the starting point is an MEA (membrane-electrode assembly) (assembly), whereby the PEM fuel cell has already been extensively tested in practice. For such PEM fuel cells, a catalyst is still necessary.

When using the PEM fuel cell as an electrolyzer - as mentioned - electrical energy must be provided. This is increasingly a wind turbine, and in particular when the wind turbine excess energy accumulates, which can not be fed directly into the grid. In this case, hydrogen can be generated as an energy source by means of the electrical power generated by the wind turbine.

In the present case, high-pressure electrolysis is carried out by designing the fuel cell as a high-pressure device. In this case, the generated hydrogen on the one hand and the oxygen produced on the other hand, under appropriate pressure. For example, pressure is generated up to 110 bar.

Since in the electrolyzer 1, the gases are not generated with the desired pressure, a compressor 5 can be connected downstream, which compresses the oxygen and the hydrogen in a suitable manner. Furthermore, the gases thus generated, ie the oxygen on the one hand and the hydrogen on the other hand, are processed via units for gas purification and closing fed to a separate tank. This means that in the tank 10, the oxygen is stored at a corresponding pressure and in the tank 20, the hydrogen with a corresponding pressure. Of the tanks 10, 20, the gases can be filled as operating or process gases, in particular for the chemical industry or other purposes in bottles 11, 21.

With the described process, it is suitably possible that the gases already compressed by the production process can be easily processed and monitored by any gas analysis systems that may be present. The storage of the gases can then take place in the pressure-resistant gas tanks 10, 20. Gas cylinders can then be filled with suitable filling devices, optionally also allowing direct filling of gas cylinders without gas tanks as a buffer.

With the last investment concept, in particular a discontinuous operation is aimed for. This means that you only operate the system when at night or at other times with low power requirements excess power from the wind turbine is available. If a further compression of the gases produced is desired, this is simplified by the already existing form. For example, an increase in pressure of 20 bar to 200 bar, the usual gas cylinder pressure, possible and can be achieved by a single-stage compressor. With such an approach, in addition to the technical simplification, a reduction in costs can be achieved in half compared to multi-stage compression systems of the prior art, which must achieve an increase in pressure from 1 bar to 200 bar. In particular, the possibility exists, the pressure ranges of the individual components, such as

Electrolyzer and compressor to match such that an economical and effective system concept is achieved. It can be shown that the operation of the electrolysis devices at higher operating pressures has a positive influence on the operating point of the system. This will be explained in detail with reference to FIG.

In FIG. 2, the abscissa represents the current density in mA / cm ² and the ordinate the voltage in volts. By way of example, measured values from experiments with atmospheric pressure are shown in comparison with measured values in tests at 100 bar, resulting in graphs 25 and 26.

Overall, it can be seen from FIG. 2 that the voltage-current density characteristics change with increasing process pressure. With increasing pressure, the resulting equilibrium voltage becomes slightly higher, but here saturates the water with gas bubbles due to their compression later. As a result, the system works more effectively at higher pressures and can therefore be operated with higher current densities. The gas yield of the system is thereby improved while maintaining the input power.

Claims

claims

A process for producing hydrogen and oxygen, in which water is subjected to an electrochemical electrolysis, characterized in that the electrolysis is carried out at pressures above atmospheric pressure, wherein a PEM high-pressure electrolysis is applied.

2. The method according to claim 1, characterized in that the high-pressure electrolysis at pressures> 10 bar, in particular

> 100 bar.

3. The method according to claim 1 or claim 2, characterized in that the PEM high-pressure electrolysis in the temperature range 5 ° C to 100 ⁰ C is operated.

4. The method according to any one of the preceding claims, characterized in that the resulting gases are stored in a high-pressure accumulator.

5. The method according to any one of the preceding claims, characterized in that the resulting gases are stored in gas cylinders.

6. The method according to any one of the preceding claims, characterized in that the hydrogen is used as an energy source.

7. The method according to any one of the preceding claims, characterized in that for the operation of the high-pressure electrolysis

Excess energy from wind turbines is used.

8. The method according to any one of the preceding claims, characterized in that by using environmentally friendly energy, the CO 2 total balance is improved.

9. The method according to any one of the preceding claims, characterized in that the high-pressure electrolysis generates a pre-pressure of about 10 bar and the further compression takes place via a mechanical compressor.

10. The method according to claim 9, characterized in that the generated gas is purified.

11. An apparatus for carrying out the method according to claim 1 or one of claims 2 to .., with an electrolyzer for the conversion of electrical energy into gaseous energy, characterized in that the electrolyzer is a high-pressure electrolyzer (1), of which the gases produced are conducted in the pressure vessel (10, 20), the high-pressure electrolyzer being an encapsulated PEM high-pressure electrolysis (1).

12. The device according to claim 11, characterized in that the electrolyzer another compressor (5) is connected downstream.

13. Device according to one of claims 11 to 14, characterized in that gas cylinders (11, 21) for direct filling of the generated gases are present.

14. Device according to one of claims 11 to 13, characterized in that units (6, 7) are present for a purification of the gases produced.