WO2008148504A2

WO2008148504A2 - Method for the isolation of hydrogen by means of a dissociation process, and dissociating apparatus

Info

Publication number: WO2008148504A2
Application number: PCT/EP2008/004309
Authority: WO
Inventors: Hermann Helmbold; Franz Wimmer
Original assignee: Conpower Energieanlagen Gmbh & Co Kg
Priority date: 2007-06-04
Filing date: 2008-05-30
Publication date: 2008-12-11
Also published as: DE102007026008B4; WO2008148504A3; DE102007026008A1; EP2155378A2

Abstract

The invention relates to a method for isolating hydrogen by means of a dissociation process as well as a dissociating apparatus according to the preamble of claims 1 and 11. In order to be able to produce or isolate hydrogen in a structurally compact and thus efficient manner such that the hydrogen can be produced in a mobile fashion and/or where needed, water and/or steam and/or a gas-water mixture and/or a biogas-water mixture is/are introduced into a reaction chamber, whereupon electromagnetic power in the microwave range is applied thereto, the ions are separated by means of an electric field, and hydrogen is withdrawn in the area of an electrode.

Description

Process for the recovery of hydrogen from dissociation, and dissociation itself.

The invention relates to a method for the production of hydrogen from dissociation, as well as dissociation device itself, according to the preamble of claim 1 and 11.

With regard to the current climate problem, the greenhouse effect is a central problem. This is largely determined by the use of fossil fuels and energy sources.

In addition, there are scarce resources of such energy sources. In this sense, alternatives are already on the rise. In addition to the renewable raw materials, for example from biomass, hydrogen plays an increasing role. The dissociation of water to split off the hydrogen is an exothermic or energy-consuming process. In this case, the operation of a conventional dissociation, for example, via the electrolysis is a possibility that requires high energy to be introduced. If these electrolysis processes are operated using conventional, ie fossil, electricity, their overall energy balance is so poor that it is not worthwhile for the large-scale use of hydrogen produced for this reason alone. Not ecologically either. For this reason, such processes are increasingly operated via solar energy. This is already much better with regard to an ecological energy balance.

From JP 2006 34 56 49 a method and a device is known in which, or in which hydrogen is produced exclusively from the classical electrolysis. The power required for this purpose is obtained from wind energy in this known method.

Alternatively, it would also be possible to obtain the required electricity from solar systems.

The disadvantage is only that the hydrogen can then only be obtained where large amounts of solar or wind energy are available. This means that the hydrogen thus produced must be transported over long distances to the point of consumption.

The invention is therefore based on the object, a method for hydrogen production and a dissociation of the generic type to the effect that hydrogen in a structurally compact manner and thus can be generated or generated efficiently, so that it can be generated mobile and / or at the place of need.

The stated object is achieved according to the invention in a method of the generic type by the characterizing features of claim 1.

Core of the inventive method is that in a reaction space water and / or water vapor and / or a gas-water mixture and / or a biogas-water mixture and then applied with electromagnetic energy in the microwave range, and that a separation of the ions takes place via an electric field, and hydrogen is withdrawn in the region of an electrode.

Electromagnetic energy acts on the bonds of the hydrogens in the molecules to relax them considerably. This creates free hydrogen from the loosened and ultimately tearing bonds.

Here, hydrogen is in a kind

Transmission method generated. Thus, hydrogen can be generated continuously and used as an energy carrier

Power generating device to be supplied. In this way, the hydrogen is generated as needed and not removed from a reservoir.

In a further advantageous embodiment, it is therefore provided that the reaction space or the medium passed through the reaction space is additionally subjected to ultrasound. The combination of ultrasonic energy and electromagnetic energy proves to be very effective in terms of

Hydrogen production. In the ultrasonic energy fed into the liquid medium, the effect of cavitation is utilized.

Especially with regard to the additionally introduced ultrasonic energy, the method is currently only applicable in liquids. Nevertheless, gases can also be used if they are previously introduced into the liquid, ie into water. Regarding the liquid as well as those introduced into the liquid Gases in this case the efficiency is significantly higher than when an admission of the gas in the gas phase.

Another point here is the technical implementation, namely that for ultrasonic generation and

Injection Piezo generators used for effective coupling to the medium must be coupled to liquids.

It is further advantageous to supply an electromagnetic energy which is in the frequency range of the microwave energy, i. in a range around 1.25 GHz +/- 250 MHz. Microwave generators of known type can therefore be used here in a simple manner.

In a further advantageous embodiment, it is provided that the ultrasonic oscillation and / or the electromagnetic oscillation are generated as pulse packets with optionally modulated higher-frequency upper oscillations, and the medium is subjected to pulses in this way. The pulsing produces, so to speak, a square wave in which the half period is given by the duration of the pulse. On the square pulse is then modulated on the high-frequency, for example, 1.25 Mhz oscillation. In this case, further higher-frequency components in the pulse packets can be modulated. It is essential only that the selected frequency resonantly coupled to the hydrogen bonds to be dissolved. For this purpose, harmonic and subharmonic frequencies can also be selected. By way of this the yield of recovered free hydrogen can be adjusted or influenced.

In a further advantageous embodiment is indicated that the process for the recovery of hydrogen within a precursor of a hydrogen combustion engine or a

Hydrogen energy device such as piston engine or turbine or a fuel cell is applied.

In a particularly advantageous embodiment, it is stated that the need for hydrogen in the

Hydrogen energy device in operation always currently generates at least one control value for the production of hydrogen, so that power query and hydrogen demand form a loop. Thus, the hydrogen is no longer taken from a reservoir or a rigid gas pipeline network, but the hydrogen is generated as needed.

To further improve the effect of hydrogen production from the removal of the same from chemical bonds of the medium is specified that the water or the water-steam mixture or the

Water-gas mixture or the water-biogas mixture before reaching the reaction space liquid catalyst materials such as surfactants are added. By means of these liquid catalyst substances, a reduction of cohesive forces takes place, which is the

Promote hydrogen recovery process.

With regard to a device, it is therefore provided that the dissociation device has a reaction space through which water and / or water vapor and / or a gas-water mixture and / or a biogas-water mixture can be passed, and also a microwave generator at the reaction space is arranged, the reaction space, or the medium conducted therethrough with electromagnetic energy in Mikrowellenbreich is acted upon, and the hydrogen ions via at least one angeordente in the reaction chamber electrode is removable as a gas.

In a further advantageous embodiment of the dissociation device according to the invention, it is proposed that the conveyed medium can additionally be acted upon by ultrasound energy via an ultrasound generator. The combination of ultrasound and microwave exposure is particularly effective for the production of hydrogen, which then serves as an energy source and can be used immediately if necessary.

Thus, this device is suitable for the production of hydrogen as a precursor for a

Piston engine, an internal combustion engine in general, or a turbine. Thus, mechanical and / or electrical and / or thermal energy is obtained from the hydrogen produced.

For direct electrical energy generation downstream of a hydrogen fuel cell is advantageous.

Overall, hydrogen is initially generated during operation of this method or in a corresponding device. In this case, the long-chain molecules are split by the combinatory effect of cavitation effect and microwave energy from the gas introduced so that on the one hand shorter molecular chains are generated, which are of greater energetic further benefit, and also falls to hydrogen, which is used in the manner described , or can be. With regard to an advantageous use of the dissociation device according to the invention, it results that the device is used as an integrated preliminary stage for a vehicle. The technique according to the invention has a compact construction and can thus be readily integrated into a vehicle.

With respect to a use according to the invention, it is stated that the dissociation device according to any one of claims 11 to 14, operated by a method according to any one of claims 1 to 10, can be used as a combined gas filter and hydrogen generator. It can fulfill both technical functions almost simultaneously. This extends the application possibilities.

In a further embodiment, it is stated that the dissociation device is used or integrated in a combined heat and power plant (CHP). Due to the compact design, this is easily possible. In doing so, the device can also be integrated into the force / heat or energy / heat process with regard to heat surpluses.

The invention is illustrated in the drawing and explained in more detail below.

It shows:

Figure 1: Schematic representation of the components of a Dissoziationseinrichtung.

Figure 2: Use in a combined heat and power plant Figure 1 shows a schematic structure of all important components in one embodiment.

The reaction space 1 is flowed from the left with a gas-water mixture. The water is previously fed to a gas-water mixer, which can be optionally but not exclusively flowed with gas. It is generated from the supplied water or gas-water mixture in the reaction chamber by microwave energy of the microwave generator 3 hydrogen. In this example, to enhance the hydrogen yield, sound energy is also supplied by the ultrasonic generator 2 as an option to the microwave energy. The combination of cavitation effect and spin-coupling effects on the hydrogen or hydrogen bonds very effectively generates hydrogen.

However, in addition to the water supplied via the gas-water mixer 4 also gas can still be supplied, from which, inter alia, hydrogen can be split off. These can be biogas or methane or other gases. In the event that additionally an additional filter effect is to be used, exhaust gases, for example tarry exhaust gases with long-chain molecules can also be added.

In the reaction space, the cleavage of the molecules, and the cleavage of the water molecule itself takes place. This produces, inter alia, hydrogen which can subsequently be collected and withdrawn from a corresponding electrode 6. This electrode may be a hollow electrode through which the captured hydrogen can be removed at the same time. At the same time there again takes place a separation of gas and water, in a gas-water separator. 5 The hydrogen 7 is withdrawn through the hollow electrode 6 and the remaining gas 8 at the end of the gas-water separator. 5

Both gases are energetically usable. Hydrogen can generate mechanical energy with the help of the known oxyhydrogen gas reaction in a piston engine, which can either be used as kinetic energy, or is emitted. In addition, the hydrogen can also be supplied to a fuel cell for direct power generation.

In the rest of the gas 8, a corresponding energy use can also be made.

At the output of the energy device 9, the water can be fed back as waste product of a detonating gas reaction or the previously separated again in the gas-water separator 5 water to the input of the gas-water mixer.

Overall, this creates a closed Wasserkeislauf in which the resulting residual heat in turn remains in the system and in turn can be used.

FIG. 2 shows an exemplary embodiment in which a dissociation device according to FIG. 1 can be integrated in a plant of a combined heat and power plant CHP 20. The combined heat and power plant, like the energy device 9 in FIG. 1, is operated with hydrogen 7 and / or purified gas 8. Hydrogen can be converted into an oxyhydrogen gas reaction and used mechanically and / or thermally. Or else it will be right in a fuel cell flows while the resulting waste heat is also used.

There are also known methane fuel cells, so that other gases can be emitted directly.

The reaction water is passed through a heat turbine, so that the heat generated there can also be used again to either nachverstromen this or feed the heat into a heat network 40.

The output of the CHP 20 thus provides both electrical and / or mechanical energy and heat energy.

In the various uses mentioned, it follows from the fact that the entire device is compact that it can also be integrated as a unit in a vehicle or a combined heat and power plant.

In the case of an application in the vehicle results in an advantageous self-sufficient thus movable assembly.

Reference numerals:

1 reaction chamber 2 ultrasonic generator

3 microwave generator

4 gas water mixer

5 gas exhaust room with gas-water separator

6 electrode with exhaust port 7 hydrogen gas outlet

8 gas water outlet

9 energy plant (fuel cell, piston engine etc)

10 Water recirculation from oxyhydrogen gas reaction

20 combined heat and power plant CHP

21 heat turbine

30 electrical network 40 heating network

Claims

claims

1. A process for the production of hydrogen from dissociation, characterized in that water and / or in a reaction space

Water vapor and / or a gas-water mixture and / or a biogas-water mixture is introduced and then acted upon by electromagnetic energy in the microwave range, and that a separation of the ions takes place via an electric field, and hydrogen is withdrawn in the region of an electrode ,

2. The method according to claim 1, characterized in that the reaction space or by the

Reaction space passed through medium is additionally subjected to ultrasound.

3. The method according to claim 1 or 2, characterized in that the hydrogen is obtained during a continuous supply or passage of the medium.

4. The method of claim 1, 2 or 3, characterized in that the frequency of the microwave energy is in a range around 1.25 GHz +/- 250 MHz.

5. The method according to claim 1 or claim 4, characterized in that the ultrasonic vibration and / or the electromagnetic vibration as pulse packets with optionally modulated higher frequency

Harmonics are generated, and the medium is applied in this way with pulses.

6. The method according to any one of the preceding claims, characterized in that the method for recovering hydrogen within a precursor of a hydrogen combustion engine or a Wassserstoffenergieeinrichtung such as engine or turbine or fuel cell is made.

7. The method according to any one of the preceding claims, characterized in that the demand for hydrogen in the hydrogen energy device in operation always currently generates at least one control value for hydrogen production, such that power query and hydrogen demand form a control loop.

8. The method according to any one of the preceding claims, characterized in that the water or the water-steam mixture or the water-gas mixture or the water-biogas mixture before reaching the reaction space liquid catalyst materials such as surfactants are added.

9. The method according to any one of the preceding claims, characterized in that the energy thus obtained in the energy generating means of hydrogen is fed back to a part for the operation of hydrogen production.

10. The method according to any one of the preceding claims, characterized in that in this closed process resulting heat surplus is used by heat pumping technology and, if appropriate, post-flow in a low-temperature heat turbine.

11. Dissociationseinrichtung for hydrogen production, characterized in that the dissociation means comprises a reaction space (1) through which water and / or water vapor and / or a gas-water mixture and / or a biogas-water mixture can be passed, and further at the reaction space (1) a microwave generator (3) is arranged, via which the reaction space (1), or the medium passed therethrough can be acted upon with electromagnetic energy in Mikrowellenbreich, and the hydrogen ions via at least one in the reaction chamber (1) arranged electrode (6) as a gas is removable.

12. dissociation device for the production of hydrogen according to claim 11, characterized in that the conveyed medium can be acted upon additionally with ultrasonic energy via an ultrasonic generator.

13. Dissoziationseinrichtung according to claim 11 or 12, characterized in that the device as an integrated precursor for a vehicle.

14.Dissoziationseinrichtung according to claim 11 or 12, characterized in that the device as a precursor for a fuel cell.

15. Use of a dissociation device according to one of claims 11 to 14, operated by a method according to one of claims 1 to 10, as a combined gas filter and hydrogen generator.

16.Use according to claim 15, characterized in that the dissociation device according to

Claims 11 to 14 and / or the method according to one of claims 1 to 10 in a combined heat and power plant (CHP) is used with.