WO2020156734A1 - Process for the energy-efficient preparation of co - Google Patents

Abstract

The present invention relates to a process for the preparation of CO from CO2 and to an apparatus for carrying out said process.

Description

description

Process for the energy-efficient production of CO

The present invention relates to a method for the produc- tion of CO from CO2, and an apparatus for performing the method.

State of the art

Around 80% of the world's energy requirements are currently covered by the combustion of fossil fuels, the combustion processes of which cause around 34,000 million tons of carbon dioxide to be emitted into the atmosphere each year. As a result of this release into the atmosphere, most of the carbon dioxide is disposed of, which can be up to 50,000 tons per day, for example in a lignite-fired power plant. Carbon dioxide is one of the so-called greenhouse gases, the negative effects on the atmosphere and the climate are discussed. A technical challenge is _to produce value-added products from CO2. Since carbon dioxide is thermodynamically very low, it can only be difficult to reduce it to recyclable products, which has actually left the actual recycling of carbon dioxide in theory or in the academic world.

Natural carbon dioxide degradation takes place, for example, through photosynthesis. In this process, carbon dioxide is converted into carbohydrates in a process that is divided into many sub-steps in terms of time and on a molecular level. This process is not easily adaptable on a large scale. A copy of the natural photosynthesis process with large-scale photo catalysis has not been sufficiently efficient so far.

An alternative is the electrochemical reduction of carbon dioxide. Systematic investigations of the Electrochemical reduction of carbon dioxide is still a relatively young field of development. Only a few years ago there have been efforts to develop an electrochemical system that can reduce an acceptable amount of carbon dioxide. Laboratory-scale research has shown that for

Electrolysis of carbon dioxide preferably metals are to be used as catalysts. From the publication Electrochemical C0 ₂ reduction on metal electrodes by Y. Hori, published in: C. Vayenas, et al. (Eds.), Modern Aspects of Electrochemistry, Springer, New York, 2008, pp. 89-189, for example, Faraday efficiencies can be taken from different metal cathodes, see Table 1, which is taken from there. Table 1: Faraday efficiencies for C0 ₂ at different

Electrodes

In Table 1, Faraday efficiencies FE [%] of products are shown that result from the reduction of carbon dioxide on different metal electrodes. The specified values apply to a 0.1 M potassium bicarbonate solution as electrolytes.

If carbon dioxide is reduced almost exclusively to carbon monoxide on silver, gold, zinc, palladium and gallium cathodes, for example, a multitude of hydrocarbons are formed as reaction products on a copper cathode.

For example, carbon monoxide and little hydrogen would predominantly be produced on a silver cathode. The reactions at the anode (with water) and cathode can be represented with the following reaction equations:

Cathode: 2 C0 ₂ + 4 e + 4H ⁺ -> 2 CO + 2 H ₂ 0

Anode: 2 H ₂ 0 -> 0 ₂ + 4 H ⁺ + 4 e

For example, the electrochemical production of carbon monoxide, ethylene or alcohols is of particular economic interest.

Examples:

Carbon monoxide: C0 ₂ + 2 e + H ₂ 0 -► CO + 2 OH

Ethylene: 2 C0 ₂ + 12 e + 8 H ₂ 0 -► C ₂ H ₄ + 12 OH

Methane: C0 ₂ + 8 e + 6 H ₂ 0 -► CH ₄ + 8 OH

Ethanol: 2 C0 ₂ + 12 e + 9 H ₂ 0 -► C ₂ H ₅ OH + 12 OH

Monoethylene glycol: 2 C0 ₂ + IO e + 8 H ₂ 0 -► HOC ₂ H ₄ OH + 10 OH

The energy efficiency of the single-stage electrochemical reduction of C0 ₂ depends not only on the overvoltages on the electrodes, the ohmic losses in the electrolyte and / or on the membranes, but also on the selected mode of operation of the electrolysis cell (stacks), since the electrolysis cell operates asymmetrically becomes. For example, C0 _{2 is} reduced at the cathode and H ₂ 0 is oxidized at the anode. To ensure continuous operation, the side reactions or buffer reactions of the reaction by-products (hydroxide, proton, hydrogen carbonate formation) must also be considered. The minimum voltage of a cell can be derived from the enthalpy of combustion from CO to CO2, since electrolysis is purely formal the reversal of the combustion. Analogously, these considerations naturally also apply to other possible reaction products of electrochemical CO ₂ reduction, such as ethylene, ethanol, methane, acetate, formic acid, formate, etc.

This is considered theoretically below.

Since electrolysers are not in thermal equilibrium with their surroundings and are therefore operated adiabatically, reaction enthalpies ÄH are expected below for these theoretical considerations.

In principle, an invoice with free reaction enthalpies ÄG delivers the same result.

C0 _{2 ->} CO + U 0 ₂ DH = 283, 16 kJ / mol CO

Divide this number by the Faraday constant

(96485.33289 C / mol) and the number of electrons transferred (z = 2), the minimum voltage for the reaction is 1.47 V.

For modes of operation as described in "Technical photosynthesis involving CO2 electrolysis and fermentation", Thomas Haas, Ralf Krause, Rainer Weber, Martin Dernier and Guenter Schmid, Natu re Catalysis, Vol 1, JAN 2018 | 32-39,

https://doi.org/10.1038/s41929-017-0005-l are presented, the minimum voltages of the single cell are slightly above 2 V, if one considers the IV characteristics of current densities in the range of several 100 mA / cm ² to a current extrapolated from 0 mA / cm ² .

With very small current densities in the range far below 1 mA / cm ² , the same extrapolation results in voltages in the range of 1.5V as from Rosen, BA; Salehi-Khoj in, A.; Thorson, MR; Zhu, W .; Whipple, DT; Kenis, PJ; Masel, RI, "Ionic liquid-mediated selective conversion of CO2 to CO at low overpotentials", Science 2011, 334 (6056), 643-4. The behavior is characterized by a co-catalytic effect that is used as an electrolyte ionic liquid explained.

However, this could not be confirmed in our own experiments at current densities above 50-100 mA / cm ² , as in Neubauer, SS; Schmid, B .; Reller, C .; Guldi, DM;

Schmid, G., "Alkalinity Initiated Decomposition of

Mediating Imidazolium Ions in High Current Density CO2 Electrolysis ", Chemelectrochem 2017, 4 (1), 160-167 reports.

An explanation of this observation can be provided by considering the half-cell potentials including the aqueous electrolyte solution.

As an anode reaction, water oxidation with the half-cell potential derived below is always considered.

2 H ₂ 0 - 4e- -> 0 ₂ + 4H ⁺ DH = 571.7 kJ

With z = 4 one obtains U _A = 1.48 V.

The cathode reaction to produce carbon monoxide is: C0 ₂ + H ₂ 0 + 2e- -> CO + 20H- DH = 108.8 kJ

With z = 2 one obtains U _K = 0.56 V.

The cell voltage results from U _z = U _A + U _K = 2.04 V.

The representation used does not correspond to the convention, since DH = -zFE normally applies. However, the minus sign is omitted for clarity. The received Tension therefore has the same sign as UH, so that the reasoning is easier to understand.

If the sum of the cathode and anode reaction is formed and the stoichiometry is correct, the cell voltage for the reaction 2 CO2 -> 2 CO + O2 in aqueous media is 2.04 V, in contrast to 1.47 V in the gas phase analysis . This means that when reducing CO2 to CO in aqueous media, from a purely thermodynamic perspective, more electrical energy must be used than would be required for the actual reduction.

This energy is in the cathode compartment, as in "Technical photo-synthesis involving CO2 electrolysis and fermentation",

Thomas Haas, Ralf Krause, Rainer Weber, Martin Dernier and Guenter Schmid, Nature Catalysis, Vol 1, JAN 2018 | 32-39 be described as thermal energy released by the absorption of C0 ₂ : OH- + C0 _{2 ->} HC0 ₃ M DH = 66, 37 kJ. With z = 1 this can be assigned to a potential of 0.69 V.

Part of this thermal energy can be used to decompose CO2 in the anode compartment from hydrogen carbonate:

H ⁺ + HCO3 -> C0 ₂ + H ₂ 0 DH = 10.57 kJ. With z = 1 this can be assigned to a potential of 0.11 V. This means that - if you summarize the thermal energy balance in the cathode and anode compartment - at least the neutralization energy must be applied as electrical energy in addition to the thermodynamic decomposition voltage if the reduction from CO2 to CO is to be carried out in aqueous media.

H ⁺ + OH- -> H ₂ 0, DH = - 55, 86 kJ

With z = 1 this can be assigned to a potential of -0.58 V.

In other words: electrical energy is unintentionally converted into thermal waste heat. Unfortunately, this waste heat is below the difficult to use temperature level of 100 ° C and can usually be regarded as an inevitable loss.

In addition to electrolysis in aqueous media, there is also a high-temperature variant that is followed by the Haldor Topsoe company. Since the main charge carrier 0 ² is transported directly from cathode to anode here, the thermal energy loss does not occur here. Because the technology is based on fragile ceramic materials, scaling into the megawatt range seems difficult. In addition, the high operating temperatures create additional thermal stress, which complicates the long-term stability of the operation.

Cathode reaction: CO2 + 2e- - CO + 0 ² ÄH = 1249, 47 kJ

With z = 2 one obtains U _K = 6.48 V.

Anode reaction: 2 0 ² - 4e- - O2 DH = -1933.01 kJ

With z = 4 one obtains U _A = -5, 01 V.

As expected, the cell voltage is 1.47 V.

The object of the present invention is to largely avoid the conversion of valuable electrical energy into thermal waste heat by means of a suitable sequence of electrochemical and thermal processes, without going back to a complex process which is highly complex and difficult to scale.

Summary of the invention

The inventors have found that the waste heat and energy loss can be reduced or even avoided by decoupling the generation of the CO from the cathode reaction.

In a first aspect, the present invention relates to a method for producing CO from CO2 comprising electrolytic conversion of a starting material comprising CO ₂ to a mixture comprising formic acid and / or formate in a first electrolytic cell,

Removing the mixture comprising formic acid and / or formate,

Introducing the mixture comprising formic acid and / or formate into a first reactor, and

Releasing a product comprising CO from the mixture comprising formic acid and / or formate in the first reactor.

The invention also relates to a process for the electrolytic conversion of a starting material comprising CO to a mixture comprising at least one hydrocarbon, the reaction being carried out in the presence of a basic electrolyte, preferably the anode comprising Fe, Ni and / or NiFe.

In addition, a device for producing CO from CO _{2 is} disclosed, comprising

a first electrolysis cell comprises a first cathode and a first anode for the electrolytic reaction of a starting material CO _2, which is comprising comprising a mixture comprising formic acid and / or formate adapted to fully implement a reactant umfas send CO ₂ to a mixture of formic acid and / or formate ;

a first supply device for an educt comprising CO ₂ to the first electrolytic cell, which is designed with the first electrolytic cell to supply an educt comprising CO _{2 to} the first cathode;

a first discharge device for a mixture comprising formic acid and / or formate, which is connected to the first electrolytic cell in a region between the first cathode and the first anode and which is designed to produce a mixture comprising formic acid and / or formate from the first Dissipate electrolytic cell;

a first reactor for releasing a product comprising CO from the mixture comprising formic acid and / or formate, which is designed to produce a product comprising CO from the Mixture comprising formic acid and / or formate to release;

a second feed device for the mixture comprising formic acid and / or formate, which is connected to the first reactor and is designed to supply the mixture comprising formic acid and / or formate to the first reactor; and

a second discharge device for discharging the product comprising CO from the first reactor, which is designed to discharge the product comprising CO from the first reactor.

Further aspects of the present invention are set forth in the dependent claims and the detailed description.

Description of the figures

The accompanying drawings are intended to illustrate and provide further understanding of embodiments of the present invention. In connection with the description, they serve to explain concepts and principles of the invention. Other embodiments and many of the advantages mentioned arise with respect to the drawings.

The elements of the drawings are not necessarily drawn to scale with respect to one another. Identical, functionally identical and identically acting elements, features and components are provided with the same reference symbols in the figures of the drawings, unless stated otherwise.

Figures 1 to 4 show schematically theoretical stages of the electrochemical conversion of CO2 to CO.

Figures 5 to 8 schematically show theoretical stages of the electrochemical conversion of CO2 in acid.

FIGS. 9 to 12 show schematically energetic considerations for the conversion of CO2 to CO via various electrochemical routes. FIG. 13 schematically shows an exemplary device according to the invention for producing CO from CO2.

FIGS. 14 to 16 show results from reference measurements in the examples according to the invention.

Detailed description of the invention

Definitions

Unless otherwise defined, technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art.

Quantities in the context of the present invention relate to% by weight, unless stated otherwise or can be seen from the context.

In the context of the present invention, hydrophobic is understood to mean something which repels serum. Hydrophobic pores and / or channels are therefore those that repel water. In particular, according to the invention, hydrophobic properties are associated with substances or molecules with non-polar groups.

In contrast, the ability to interact with water and other polar substances was understood to be hydrophilic.

Gas diffusion electrodes (GDE) in general are electrodes in which liquid, solid and gaseous phases are present, and where in particular a conductive catalyst can catalyze an electrochemical reaction between the liquid and the gaseous phase.

The design can be of different types, for example as a porous “solid catalyst” with possibly auxiliary layers to adjust the hydrophobicity, or as a conductive porous carrier on which a catalyst in thin

Layer can be applied.

For the purposes of this invention, a gas diffusion electrode (GDE) is in particular a porous electrode, inside which gases can move through diffusion. For example, it can be designed to separate a gas and an electrolyte space from one another. According to certain embodiments, it can be characterized in that product gases can escape from these gas diffusion electrodes on the side facing away from the counterelectrode, that is to say, for example, into a gas space to which a gas is supplied for conversion. Liquids and / or dissolved products and / or by-products of the electrochemical conversion, in particular the charge carriers generated thereby, can be released, for example, from the electrode into the electrolyte. A GDE can be built up in one or more layers with hydrophilic and / or hydrophobic regions, with at least one hydrophobic layer being advantageous, for example, for good contacting of a gas comprising CO2, while a hydrophilic layer can be advantageous for good contacting of an aqueous electrolyte . GDEs are in particular electrodes in which liquid, solid and gaseous phases are present and where the conductive catalyst catalyzes the electrochemical reaction between the liquid and the gaseous phase.

The normal pressure is 101325 Pa = 1.01325 bar.

Electro-osmosis:

Electro-osmosis is an electrodynamic phenomenon in which a force towards the cathode acts on particles in solution with a positive zeta potential and a force towards the anode on all particles with a negative zeta potential. If there is a conversion at the electrodes, ie if a galvanic current flows, there is also a material flow of the particles with positive zeta potential to the cathode, regardless of whether the species is involved in the conversion is divided or not. The same applies to a negative zeta potential and the anode. If the cathode is porous, the medium is also pumped through the electrode. One also speaks of an electro-osmotic pump.

The material flows caused by electro-osmosis can also flow in the opposite direction to concentration gradients. Diffusion-related currents that compensate for the concentration gradients can thus be overcompensated. For example, this may involve a flow of carbonate and / or hydrogen carbonate ions in the first electrolytic cell.

A separator is a barrier, for example a layer, which in an electrolysis cell has a spatial and at least partially also material separation between different spaces of the electrolysis cell, e.g. Anode compartment, electrolyte compartment, salt bridge compartment, cathode compartment, etc., as well as an electrical separation between anode and cathode, but allow ion transport between the different compartments. In particular, a separator does not have a permanently assigned potential, like an electrode. A separator can, for example, be a flat barrier with the same surface area. In particular, membranes and diaphragms can be seen as special examples of separators.

In a first aspect, the present invention relates to a method for producing CO from CO ₂ comprising

electrolytic conversion of a starting material comprising CO ₂ to a mixture comprising formic acid and / or formate in a first electrolytic cell,

Removing the mixture comprising formic acid and / or formate,

Introducing the mixture comprising formic acid and / or formate into a first reactor, and

Releasing a product comprising CO from the mixture comprising formic acid and / or formate in the first reactor. The sequence of the steps in the process takes place in the order named.

The product comprising CO is also suitable for pressure build-up. In particular, the product comprising CO, according to certain embodiments, is also low in H2, because it can be produced in a separate container, a first reactor.

The educt comprising CO2 is not particularly limited and can be used, for example, as a gas mixture, which can also be moistened, for example, for better contacting of an electrode - here e.g. a first cathode, or solution. In addition to CO2, there may also be other gas components, but preferably essentially CO2 is present in the starting material, for example more than 50, 90, 95 or 99% by volume, and up to 100% by volume.

The electrolytic conversion is also not particularly restricted, in particular the anode reaction is not particularly restricted and can be, for example, the conversion of water. Accordingly, the first electrolytic cell is not particularly limited if it has a first cathode and a first anode. The two electrodes, that is, the first cathode and the first anode, are not particularly limited. According to certain embodiments, the first cathode is a gas diffusion electrode. Here, an educt comprising CO2 is introduced into the electrolysis cell and reduced on the cathode side using the GDE, a liquid, preferably aqueous, electrolyte being able to be present on the other side. According to certain embodiments, the first anode is a gas diffusion electrode.

A mixture comprising formic acid and / or formate is formed in the electrolytic reaction, the mixture also being able to contain other components such as other products of the electrolytic reaction, but preferably in the reaction Settlement essentially results in formic acid and / or formate, preferably more than 50, 90, 95 or even 99% by weight, based on the CO2 that is converted. According to certain embodiments, a mixture comprising formic acid is formed. In certain embodiments, a mixture of formate is formed. This can depend, for example, on an electrolyte in the electrolytic reaction.

This mixture comprising formic acid and / or formate is discharged from the first electrolytic cell in a suitable manner, which is not particularly limited, and can be carried out, for example, in cocurrent or countercurrent to supplying the starting material comprising CO2, for example via a suitable discharge device.

After removal, the mixture comprising formic acid, if appropriate after passing through a container for intermediate storage, is introduced into a first reactor in which a product comprising CO is released from the mixture, the release being not restricted here and also dependent on it whether there is essentially formic acid or formate.

For the method according to the invention for producing CO from CO2, the above theoretical considerations regarding cell voltage are now further discussed, which now form the basis of the present invention. As explained above, thermal energy is generated as an unusable energy loss in the electrolytic conversion of CO2 to CO in aqueous media.

In aqueous media, energy loss could be avoided if work could be done in acidic media.

Cathode reaction: CO2 + 2 H ⁺ + 2e -> CO + H2O ÄH = -2.87 kJ

With z = 2 one obtains rounded U _K = -0.01 V:

Anode reaction: 2 H2O - 4e- - ^ 02 + 4H ⁺ ÄH = 571.7 kJ With z 4 you get rounded U _A 1.48 V.

The cell voltage is again rounded to 1.47 V.

Unfortunately, the overvoltage of hydrogen at the usual electrodes described for converting CO2 to CO (e.g. Au, Ag) in acidic media is low, so that the CO2 reduction is greatly suppressed compared to the PUO reduction and thus almost exclusively hydrogen is produced and this variant without intensive catalyst development is not a solution to the problem.

Accordingly, this is not a practical solution, so that the theoretical considerations are now considered in more detail.

The C0 ₂ reduction takes place over several stages. A chemical intuitive idea is shown in the following reaction equations and reaction states in conjunction with Figures 1 to 4 schematically in several steps.

In Figure 1, the first step of the C0 ₂ adsorption on a surface, here an exemplary metal M, is shown. The first reduction in the electrochemical conversion, which is shown in FIG. 2, then takes place in a step 2. This is followed in a third step by a first protonation in aqueous media, which is shown in FIG. 3. Subsequently, in a step 4, which is shown in FIG. 4, a second reduction takes place, an output channel for format F (format type exit channel) also being possible, whereupon CO desorption or a further step occurs in a fifth step Reduction follows (not shown). In detail, this takes place as follows:

First, the CO2 is absorbed on the surface of the metal M in the first step and an electron is transferred in step 2, which formally increases the oxidation number of the carbon by 1. Metal carboxylates are basic and can be protonated relatively easily by water, which releases the first hydroxide ion in step 3. One can imagine that due to the stability of the metal carboxylate, relatively little energy is required for this. This is followed by the second reduction stage in step 4, which creates a “structural isomer” of the formate.

This creates two more paths.

a. The pseudoformate breaks down into a hydroxide ion and carbon monoxide, as shown in Figure 4.

b. The pseudoformate rearranges into formate and is then desorbed, as illustrated by the path to formate F.

All of these steps must overcome certain energy barriers for them to take place. This energy can be supplied either electrically or thermally. The thermodynamic considerations above show that for the CO formation via step a. considerable amounts of energy must be supplied in the form of electrical energy.

Thermodynamic considerations are path independent i.e. in principle it is not important whether the energy is supplied in the form of electrical or thermal energy. However, the usable energy share of the various forms of energy (exergy) is significantly different. Electricity is a form of energy with 100% exergy. In the case of heat, the usable energy is limited by Carnot efficiencies.

It is therefore important to consider process sequences where the electrical energy used has the most benefit and is not necessarily lost in the form of heat. The following table 2 summarizes the thermodynamic considerations. The anode reaction, which is not particularly limited - here, for example, water oxidation - is the same for both process sequences.

Table 2: Thermodynamic considerations for the reaction of CO2 to CO or format / formic acid, with regard to the thermodynamic limit of this reaction of 1.47 V

It was explained in detail above that the minimum cell voltage for the production of CO from CO2 is 2.04 V and then at least the neutralization energy in the cathode compartment is released again in the form of unwanted heat. The reference point is always the total reaction CO2 - CO + h O2 with 1.47 V. In carbon monoxide and formate / formic acid, the carbon has the same oxidation state of +2.

For the purposes of the invention, it is therefore advantageous first of all to generate formate and / or formic acid on the cathode.

C0 ₂ + H ₂ 0 + 2e - HCOO + OH DH = 23.88 kJ

With z = 2 one obtains U _K = 0, 12 V.

The anode reaction provides the necessary protons for the neutralization to formic acid in these considerations. The minimum total tension in aqueous media is 1.60 V. Formic acid can easily be thermally decomposed into CO and H2O (ÄH = -29.06 kJ, with z = 2 this would correspond formally to U = 0.15 V). This energy can possibly be applied from the waste heat of the electrolyzer.

In retrospect, the formation of the second hydroxide ion is very energy-intensive.

This results in the inventive process sequence based on the electrical energy to be used, which can be provided, for example, from renewable energies:

1. Production of formate on the cathode, which can then be neutralized with formons of the anode to formic acid.

2. Thermal decomposition of formic acid to CO and water (or formate to CO, for example with the addition of acid).

While in a direct synthesis of CO with a basic cathode reaction minimal (2.04 V - 1.47 V) / 2.04 V = 28% electrical energy is lost in the form of heat, in the case of the sequence discussed here (with the theoretical tension of the release of CO)

(1.75 V - 1.47 V) / 1.75 V = 16%. This energy can also be used, at least in part, from the waste heat of the electrolyzer for the CO release.

If you carry out the formate production in acidic electrolytes, the following half-cell voltage results:

C0 ₂ + 2 H ⁺ + 2e -> HCOO- DH = -31.92 kJ

With z = 2 one obtains U _K = -0.17 V and thus a rounded cell voltage of 1.32 V.

A chemical intuitive idea for this “acid-catalyzed path” is shown schematically in several steps in the following reaction equations and reaction states in conjunction with FIGS. 5 to 8. In FIG. 5, the first is again in accordance with FIG. 1

CCd adsorption step on a surface, here an exemplary metal M, is shown. This is followed in a second step - in accordance with the consideration in FIG. 2 - the first reduction in the electrochemical reaction, which is shown in FIG. 6. Subsequently, in contrast to the above scheme, a protonation takes place in a third step from the acidic medium, which is shown in FIG. 7. Subsequently, in a fourth step, which is shown in FIG. 8, a surface rearrangement takes place, which here enables an output channel for format F (format type exit channel), whereupon a thermal CO release can follow in a fifth step

(not shown) .

The corresponding reactions in various states and media are also shown schematically in FIGS. 9 to 12 with regard to their energy balances.

FIG. 9 shows the theoretical voltage of 1.47 V, which must be used for the gas phase conversion from CO2 to CO and which can come from renewable energy 1, for example. As stated above, the same voltage would also result from a direct conversion of CO2 to CO in acidic medium (half-cell voltage rounded at the anode in water electrolysis - 1.48 V, rounded at the cathode 0.02 V, so that rounded for the cell result in -1.47 V), which, however, has not been technically possible up to now due to the low hydrogen overvoltage on silver, for example.

In FIG. 10 it is shown that, when implemented in a non-acidic environment, additional thermal energy 3 has to be used, which has to be additionally used as energy 2, for example renewable energy. This is a result of the cathode half-cell voltage of -0.56V, so that with the same anode half-cell, a total voltage of rounded -2.04 V results. FIG. 11 shows the route via formic acid in basic form, a voltage of -0.12 V being recorded here for the cathode half-cell (formate formation) with the same anode half-cell. For the total energy 4 to be used, this results in a thermal loss 5 which, when rounded, corresponds to a voltage of 0.13 V.

FIG. 12 shows the energy balance via the formation of formic acid on the cathode side (CO2 + H ⁺ + 2 e HCOO-; U _Ha ibzeiie = -0.17 V), the energy to be used being reduced compared to the gas phase reduction in FIG. 9 6 reduced and heat loss 7 can be recycled (for water conversion as an anode reaction).

It should be noted that the convention ÄH = -z-F-E was used for Figures 9 to 12.

It should be noted in the above considerations that the anode reaction is irrelevant for aqueous electrolytes, since it brings the same energy to all half cells in the overall balance and there are only differences with regard to an acidic, neutral or basic electrolyte.

The C02 / HC03 / C03 ² / 0H balance is therefore the main problem for the energy-efficient use of renewable energy in the direct one-step electrochemical synthesis of CO2 to CO and / or to hydrocarbons.

In accordance with the theoretical considerations above, there are therefore various configurations of the method according to the invention.

In principle, two configurations are possible. One possibility is formate, the other is formic acid itself. Formation with formic acid is preferred in accordance with the above considerations. According to certain embodiments, the mixture comprising formic acid and / or formate is removed in solution, preferably in aqueous solution. This is possible, for example, when using an aqueous electrolyte, at least in the space between the first anode and the first cathode.

A less preferred embodiment of the invention is that in a, for example neutral, electrolyte (e.g. with KHCO3, K2SO4, etc.) a formate salt such as potassium formate on a suitable first cathode, e.g. an electrode containing Pb or Sn, and this is isolated by crystallization. In this case, the mixture comprising formic acid and / or formate essentially comprises a formate salt or even only a formate salt. This can then be decomposed in the first reactor. Decomposition of, for example, potassium formate takes place in the range around its melting point of 260-300 ° C. However, due to the high temperatures, this design is less preferred.

Another alternative is the use of an acid, which is not particularly restricted and which is added to the mixture comprising formic acid and / or formate in the first electrolytic cell and / or outside, for example in a container for intermediate storage and / or a first reactor can. Exemplary preferred acids are sulfuric acid and / or hydrochloric acid. The formate obtained can be neutralized and decomposed by the acid, for example sulfuric acid.

For example, the following equation is possible:

2 KOOCH + H ₂ SO _{4 ->} K ₂ SO ₄ + CO + H ₂ 0.

Sulfuric acid is a preferred acid here because it is a common commodity product. If an electrolyte containing potassium salt is used, a potassium sulfate obtained can also be used as fertilizer and / or electrolyte additive. A third possibility is to generate formic acid directly electrochemically, as described, for example, in "Electrochemical conversion of CO2 to formic acid utilizing Sustainion ™ membranes", Hongzhou Yang, Jerry J. Kaczur, Syed Dawar Sajjad, Richard I. Masel, Journal of C0 ₂ Utilization 20 (2017) 208-217, which is referred to for the generation of formic acid. Of course, other electrochemical methods for generating formic acid are also possible.

With its simple thermal decomposition into CO and H ₂ 0, the electrochemical generation of formic acid becomes a process that generates CO in a more energy-efficient manner, based on the use of electrical energy, than the electrochemical direct reduction of CO2

Formic acid conducts poorly in principle, so that to increase the conductivity in "Electrochemical conversion of C0 ₂ to formic acid utilizing Sustainion ™ membranes", Hongzhou Yang, Jerry J. Kaczu, Syed Dawar Sajjad, Richard I. Masel, Journal of C0 ₂ Utilization 20 (2017 ) 208-217, solid electrolytes are added, the conductivity of which is also limited.

The poor electrical conductivity s of formic acid in water is shown in Table 3 below.

Table 3: Electrical conductivity of formic acid at 25 ° C in a mixture with water

Accordingly, the concentration of formic acid in the mixture comprising formate and / or formic acid should not be too high, but also not too low, in order to ensure sufficient conversion. According to certain embodiments, the content of formic acid and / or formate in the mixture comprising formic acid and / or formate after the electrolytic reaction of the starting material comprising CO2 is in a range from 0.5% by weight or more and 100% by weight or less, preferably 1% by weight or more and 95% by weight or less, more preferably 5% by weight or more and 90% by weight or less.

Since the formic acid does not have to be isolated as such in the proposed process, non-volatile soluble additives for increasing the conductivity, for example in the electrolyte, can also be added to the mixture comprising formic acid and / or formate. These can also support the decomposition to CO and H2O at the same time. According to certain embodiments, an aqueous electrolyte is present in the first electrolytic cell at least between the first cathode and the first anode.

According to certain embodiments, a, preferably aqueous, first electrolyte for the electrolytic conversion of the starting material comprising CO2 to a mixture comprising formic acid and / or formate comprises an acid and / or a salt in order to increase the conductivity.

According to certain embodiments, a, preferably aqueous, first electrolyte for the electrolytic conversion of the starting material comprising CO 2 to a mixture comprising formic acid and / or formate comprises an acid and / or a formate salt and / or a sulfate salt, more preferably a liquid acid, for example sulfuric acid .

This can significantly increase the conductivity in view of the fact that the formic acid itself does not conduct enough.

For example, salts as additives can make this possible, preferably formates and / or sulfates, e.g. preferably alkali formate, preferably potassium formate, or also alkali sulfate, e.g. Potassium sulfate. These additives do not interfere with the subsequent decomposition of the formic acid, but increase the conductivity of the solution up to a factor of 10.

Adding sulfuric acid, for example, can increase the conductivity above 100 mS / cm due to the availability of free protons.

An excessively high acid concentration, for example sulfuric acid concentration, should however be avoided, since otherwise the formic acid can already decompose in the space or gap between the first cathode and the first anode, resulting in a CO, CO2, H2 separation task. The decomposition can, in addition to or in addition, also be good via a temperature control to be controlled. According to certain embodiments, the concentration of the acid in the electrolyte of the first electrolytic cell is set in a range from 0.01 to 50% by weight, for example 0.1 to 40% by weight, in particular 1 to 35% by weight. A concentration of a salt in the electrolyte of the first electrolytic cell can likewise be set in a range from 0.01 to 50% by weight, for example 0.1 to 40% by weight, in particular 1 to 35% by weight. For sulfuric acid, for example, a maximum concentration can also be up to and including 20% by weight, for example in order to enable a sufficient anode reaction. However, according to certain embodiments, it is also possible to use an acid with a concentration of 50% by weight or more, for example more than 50% by weight, in the electrolyte, but this is not preferred, since here the acid, for example Sulfuric acid, can have a dehydrating effect on the formic acid.

An acid addition, in particular sulfuric acid addition, to the (first) electrolyte in the first electrolytic cell is possible in particular if an anion exchange membrane is present on the side of the first cathode, which additionally blocks the diffusion of protons, especially at higher current densities. The anion exchange membrane is not particularly limited here and can be separate from the first cathode or bound as in a membrane electrode assembly (MEA).

According to certain embodiments, at least one anion exchange membrane, preferably in a region of the first cathode, is present between a first cathode and a first anode of the first electrolytic cell. This is particularly advantageous when using a basic electrolyte. Depending on the cathode used, it may not be present, for example if the formation of formate and / or formic acid is good at the first cathode, for example with a cathode comprising Pb. According to certain embodiments, the first electrolytic cell has at least no anion exchange membrane in a region of the cathode or even has no anion exchange membrane.

According to certain embodiments, the first electrolytic cell has a cation exchange membrane or a bipolar membrane between a first cathode and a first anode in a region of the first anode. The cation exchange membrane or the bipolar membrane are not particularly limited and can in turn be present separately or as an MEA together with the anode. In addition to controlling the ion transport, they can preferably prevent formate from migrating to the anode and being decomposed there.

According to certain embodiments, a - first - cathode of the first electrolytic cell comprises or contains a metal which is selected from Cu, Bi, Pb, Hg, In, Sn, Cd, TI and / or compounds, in particular chalcogenidic compounds, and / or alloys and / or mixtures thereof, preferably Pb, Bi, Hg, In, Sn, Cd, TI and / or compounds, in particular chalcogenide compounds, and / or alloys and / or mixtures thereof, more preferably Pb, Bi, in particular Pb. These are particularly capable of formate and / or formic acid formation. According to certain embodiments, the first cathode consists of a metal which is selected from Cu, Bi, Pb, Hg, In, Sn, Cd, TI and / or compounds, in particular chalcogenide compounds, and / or alloys and / or mixtures thereof, preferably Pb, Bi, Hg, In, Sn, Cd, TI and / or compounds, in particular chalcogenide compounds, and / or alloys and / or mixtures thereof, more preferably Pb, Bi, in particular Pb.

With the method according to the invention, the electrolytic conversion of the starting material comprising CO2 into a mixture comprising formic acid and / or formate can also take place at a practical cell voltage which is much lower than usual voltages when reducing CO2 to CO, for example at 2.5 2.7 V with common overvoltages. After the mixture comprising formic acid and / or formate has been prepared, it is suitably removed from the first electrolytic cell, for example via a tube

Hose, a line, etc. Before the mixture comprising formic acid and / or formate is introduced into the first reactor, it can be temporarily stored in a first container, for example for storage, adjustment of a suitable concentration of formic acid and / or formate (eg by evaporation), etc. In the case of intermediate stores in a first container, it can also be delivered to a further distant first reactor, so that a temporal and / or spatial separation between the first electrolysis cell and the first reactor is also possible.

According to certain embodiments, the mixture comprising formic acid and / or formate is temporarily stored in a first container after it has been removed from the first electrolytic cell and before being introduced into the first reactor.

From the first container, if present and the mixture comprising formic acid and / or formate is not introduced directly into the first reactor, for example via a tube, a hose, a line and / or another suitable connecting device, the mixture comprising formic acid and / or formate can be suitably introduced into the first reactor, for example via a tube

Hose,, a line, etc.

In the first reactor, the release of CO from formic acid and / or formate can then take place in a suitable manner, for example by setting a suitable temperature, acid concentration, and / or presence of a suitable catalyst, etc., the measures being not particularly limited and common measures can correspond to formic acid decomposition. According to certain embodiments, CO is released from the mixture comprising formic acid and / or formate in the first reactor by dehydration, preferably by heating and / or heterocatalytic Dehydration. A suitable temperature is not particularly limited here and can also depend, for example, on the pressure and / or a catalyst, etc., and can for example comprise 10-130 K, preferably 10-80 K, above the electrolyte temperature and / or the mixture Formic acid and / or formate, which is introduced into the first reactor, are, for example, in a range from 70 ° C to 190 ° C, for example 70 ° C to 150 ° C. Formic acid usually boils at normal pressure with decomposition at 101 ° C. The decomposition can also take place slowly at room temperature.

The use of at least one acid in the release of CO is particularly advantageous. A solution of acid / formic acid is liquid, ie any pressure can actually be built up during decomposition. Pressures above 1 bar (1 * 10 ⁵ Pa) are preferred, particularly preferred pressures between 30 bar (30 * 10 ⁵ Pa) and 100 bar (100 * 10 ⁵ Pa), as they occur in the chemical process industry, for example. This also saves compressors.

Of particular importance here is not the decomposition to CO, but the synergy with regard to the cell voltage during the electrolytic conversion in the first electrolytic cell, which allows a lowering of the cell voltage compared to the direct CO generation. Accordingly, CO is formed effectively. This CO can then be used in a suitable manner.

It is particularly advantageous that it can ultimately be used to efficiently produce hydrocarbons from CO2.

In contrast to CO2, CO can also be efficiently converted into hydrocarbons in a basic electrolyte. This means that common anodes can also be used here, in contrast to the usual production of hydrocarbons in a single electrolytic cell. By decoupling the CO production from the electrolytic conversion of CO2, an advantageous further implementation is also possible. According to certain embodiments, the CO produced in the process according to the invention described above is thus further converted in a second electrolytic cell to at least one hydrocarbon, the reaction preferably taking place in the presence of a second, basic electrolyte. As shown, the anode can include common metals such as Fe, Ni and / or NiFe, and the cathode material is not particularly limited either, as discussed further below.

A further aspect of the present invention relates to a process for the electrolytic conversion of a starting material comprising CO to a mixture comprising at least one hydrocarbon, the reaction taking place in the presence of a basic electrolyte, in particular anolyte, preferably with the anode Fe, Ni and / or NiFe. Here, the material of the cathode is not particularly limited and can comprise any materials which enable CO conversion, for example a metal which is selected from Cu, Ag, Pd, Pt and / or Au, preferably Cu, and / or Alloys and / or compounds thereof, and / or mixtures thereof.

The C0 ₂ / HC0 ₃ / C0 ₃ ² / 0H equilibrium affects not only the reduction product CO, but all other reduction products such as ethylene, ethanol, propanol, acetate or the trace products allyl alcohol, ethylene glycol etc.

This is explained using the example of ethylene. The overall reaction serves as a reference:

2 C0 ₂ + 2 H ₂ 0 - C ₂ H ₄ + 3 0 ₂ DH = 1411.07 kJ With z = 12 one obtains U _ceii , _min = 1.22 V.

2 C0 ₂ + 8 H ₂ 0 + 12e ^_ = C ₂ H ₄ + results in aqueous medium

12 OH DH = 365.76 kJ

With z = 12 one obtains U _K = 0.32 V. An acidic anode reaction results in a minimum cell voltage of 1.80 V. The difference again corresponds to the neutralization energy / voltage: 55.08 kJ / z = 1 / 0.58 V.

As in "Reactivity of Copper Electrodes towards Functional Groups and Small Molecules in the Context of CO2 Electro-Reductions", Bernhard Schmid, Christian Reller, Sebastian S. Neubauer, Maximilian Fleischer, Romano Dorta and Guenter Schmid; Catalysts 2017, 7, 161; doi: 10.3390 / catal7050161 ge, the reduction of CO2 and CO results in the almost identical product range in the hydrocarbon sector, which identifies CO as the most important intermediate.

The reduction of CO to hydrocarbons has a decisive advantage over that of CO2 when considering what has been presented so far. Strongly basic electrolytes are advantageous for both reactions, whereby in the case of CO2 the CO2 / HCO3 / C03 ² / 0H equilibrium must be taken into account and not in the case of CO.

This means that in the case of CO, the electrolyte (anolyte and catholyte) as a whole can be strongly basic and e.g. a KOH solution in water can be chosen. However, the basic electrolyte is not particularly limited.

The following applies:

Cathode reaction:

2 CO + 6 H ₂ 0 + 8e -> C ₂ H ₄ + 8 OH DH = 148.27 kJ With z = 8 we get U _K = 0.19 V,

Anode reaction:

4 OH - 4 e -> 0 ₂ + 2 H ₂ 0 DH = 348.44 kJ

With z = 4 one obtains U _A = 0.90 V. The minimum cell voltage is therefore: U _ceii = 1.09 V. This voltage is identical to that calculated from the sum reaction:

2 CO + 2 H ₂ 0 -> C ₂ H ₄ + 2 0 ₂ DH = 845, 14 kJ With z = 8 one obtains U _ceii = 1.09 V.

The possibility to work in the basic also means that no iridium is necessary as an anode material and the classic catalysts (Fe, Ni, NiFe etc.) of the alkali electrolytes can be used. This also avoids the disadvantage of Iridium's resource limitation.

From a broader perspective, this also means that it can make sense to use CO from fossil sources (coal power gasifier, etc.) in order to then process it with renewable electricity, e.g. to produce ethylene, in order to obtain a partially green product. CO can also originate from the decomposition of formic acid, which in turn is also accessible to CO ₂ and H ₂ by means of homogeneous catalysis.

In addition, the present invention relates to a device for producing CO from C0 ₂ comprehensively

a first electrolyte cell comprising a first cathode and a first anode for the electrolytic conversion of an educt comprising CO ₂ to a mixture comprising formic acid and / or formate, which is designed to convert an educt comprising CO ₂ to a mixture comprising formic acid and / or formate ;

a first feed device for an educt comprising C0 ₂ to the first electrolytic cell, which is designed with the first electrolytic cell to supply an educt comprising C0 _{2 to} the first cathode;

a first discharge device for a mixture comprising formic acid and / or formate, which is connected to the first electrolytic cell in a region between the first cathode and the first anode and which is designed to form a To remove mixture comprising formic acid and / or formate from the first electrolytic cell;

a first reactor for releasing a product comprising CO from the mixture comprising formic acid and / or formate, which is designed to release a product comprising CO from the mixture comprising formic acid and / or formate;

a second feed device for the mixture comprising formic acid and / or formate, which is connected to the first reactor and is designed to supply the mixture comprising formic acid and / or formate to the first reactor; and

a second discharge device for discharging the product comprising CO from the first reactor, which is designed to discharge the product comprising CO from the first reactor.

With the device according to the invention, in particular the method according to the invention for producing CO from CO ₂ can be carried out. Correspondingly, certain aspects, which are described with regard to embodiments of the method according to the invention, can also be used in the device according to the invention.

In the device, the first electrolytic cell is not particularly limited insofar as it comprises a first cathode and a first anode. The material of the cathode is not particularly limited. According to certain embodiments, the first cathode of the first electrolysis cell comprises or contains a metal which is selected from Cu, Bi, Pb, Hg, In, Sn, Cd, TI and / or compounds, in particular chalcogenidic compounds, and / or Alloys and / or mixtures thereof, preferably Pb, Bi, Hg, In, Sn, Cd, TI and / or compounds, in particular chalcogenide compounds, and / or alloys and / or mixtures thereof, more preferably Pb, Bi, in particular Pb. According to certain embodiments, the first cathode consists of a metal which is selected from Cu, Bi, Pb, Hg, In, Sn, Cd, TI and / or compounds, in particular chalcogenidic compounds, and / or alloys Stakes and / or mixtures thereof, preferably Pb, Bi, Hg, In, Sn, Cd, TI and / or compounds, in particular chalcogenidic compounds, and / or alloys and / or mixtures thereof, more preferably Pb, Bi, in particular Pb .

The first anode is not particularly limited and can be adapted to the anode reaction, and the anode material can also differ depending on whether a cation exchange membrane or a bipolar membrane is present or not.

The first feed device is not particularly limited and can be, for example, a pipe, a hose, a line, etc. Likewise, the first discharge device is not particularly limited and can be, for example, a pipe, a hose, a line, etc. A further discharge device for unreacted educt comprising CO ₂ and / or a further feed device for electrolyte and / or educt for the anode and / or further feed and / or discharge devices for the first electrolytic cell can also be present, which can also be used, for example, with other feed devices lines can be connected, for example if unreacted CO ₂ is recycled. In addition, there may be heating and / or cooling devices for the first electrolytic cell.

In addition, the second feed device and the second discharge device are not particularly limited and can be, for example, a tube, a hose, a line, etc. The second feed device may or may not be connected to the first discharge device and, for example, is not connected directly to it if a first container for the intermediate storage of the mixture comprising formic acid and / or formate is present.

The first reactor is also not particularly limited. According to certain embodiments, the first reactor comprises at least one heating device which is not particularly is limited to favor thermal decomposition of formic acid, for example at least one heat pump to use the heat from the electrolysis. If the electrolyte is returned, appropriate heat exchangers can also be provided.

According to certain embodiments, the first electrolytic cell has at least one anion exchange membrane between the first anode and the first cathode, preferably in a region of the first cathode. It can be designed as an MEA or separately from the cathode.

According to certain embodiments, the first electrolytic cell has a cation exchange membrane or a bipolar membrane between the first cathode and the first anode in a region of the first anode. These can also be provided as MEAs or separately.

According to certain embodiments, the first cathode of the first electrolytic cell comprises a metal which is selected from Cu, Bi, Pb, Hg, In, Sn, Cd, TI and / or alloys and / or mixtures thereof, preferably Pb, Bi, Hg, In , Sn, Cd, TI and / or alloys and / or mixtures thereof, further preferably Pb, Bi, in particular Pb.

According to certain embodiments, the device according to the invention further comprises a first container for intermediate storage of the mixture comprising formic acid and / or formate, which is arranged between the first discharge device and the first supply device and which is designed to comprise the mixture comprising formic acid and / or Caching formate. The first container is not particularly limited. It can comprise a third discharge device, which is designed to discharge the mixture comprising formic acid and / or formate after the intermediate storage. The third discharge device may or may not be connected to the second feed device. The first container can also have further discharge devices, for example for unreacted CO2 and / or decay products of formic acid and / or water, which can be evaporated to concentrate formic acid and / or formate. Correspondingly, the first container can also comprise at least one heating device.

The above embodiments, refinements and developments can, if appropriate, be combined with one another as desired. Further possible refinements, developments and implementations of the invention also include combinations of features of the invention described above or below with reference to the exemplary embodiments, which are not explicitly mentioned. In particular, the person skilled in the art will also add individual aspects as improvements or additions to the respective basic form of the present invention.

The invention is explained in more detail below with reference to various examples thereof. However, the invention is not limited to these examples.

Examples

example 1

An exemplary method according to the invention and an exemplary device according to the invention are shown schematically in FIG.

The formic acid is produced electrochemically in the first electrolytic cell 10 on the first cathode 11, with water being electrolyzed as the electrolyte on the first anode 12. At the first anode 12 there is a cation exchange membrane, and at the first cathode 11 an anion exchange membrane AEM. The starting material comprising CO2 is supplied via the first feed device 13, and the mixture comprising formic acid is fed via the first discharge device by means of the line 14 to a first container 20. About that In addition, an outlet for oxygen is provided on the anode side.

In the container 20, the mixture comprising formic acid is temporarily stored, which preferably serves at the same time for the separation of further gas such as excess CO2 or the by-products H ₂ or CH ₄ . This vessel can, but does not have to, serve as an electrolyte reservoir and / or formic acid store. Electrolyte can, for example, be returned via line 15 to the first electrolytic cell 10, and likewise not converted CO2 via line 16.

The process chain can also be spatially and temporally separated at this point. The formic acid content can be, for example, between 1 and 100%, and can be adjusted to a preferred limit in the range of 5 to 90% in the course of the electrolysis. After transferring the mixture to formic acid via line 21, pure CO is then released in the second process step in the first reactor 30 by dehydrating the formic acid, as a result of which the formic acid content drops again. The decomposition is achieved, for example, by heating or heterocatalytic dehydration, which are not shown in detail. Via line 22, non-decomposed formic acid can be returned to the first container 20.

In the first container 20, for example, a suitable temperature of, for example, 60 ° C. can be set for storage, the electrolyte here also being able to be buffered if necessary. In the first reactor, the temperature can then be raised to a suitable temperature of, for example, 10 to 80 K above the electrolyte temperature and / or compression can take place in order to facilitate the release of CO. Depending on the decomposition - for example with a suitable catalyst - low CO ₂ or even CO ₂ free CO can be obtained. Example 2

The structure corresponds to that of Example 1, with a bipolar membrane being used instead of a CEM.

Example 3

The structure corresponds to that of Example 1, but there is no AEM on the cathode side and in particular a Pb-containing cathode is used. For example, the overvoltage on lead electrodes for hydrogen is very high, so that it may also be possible to work in acidic electrolytes (see also Example 5). As described above, lead electrodes provide formate in CCh electrolysis. The local pH of the electrode becomes more basic the higher the current density at which it is operated, i.e. it is expected that the formate yield will be even higher at higher current densities than at lower ones.

Example 4

In the structure of Example 1, water with a salt such as KSO is used instead of water as electrolyte.

Example 5

In the structure of Example 1, water with an acid such as sulfuric acid is used as the electrolyte instead of water. In this example in particular, the AEM can also be dispensed with, in particular if the first cathode comprises 11 Pb. It is advantageous here that the Pb has a high overvoltage over hydrogen of -0.71 V.

Reference example 1

Conductivity measurements were carried out for various mixtures of formic acid as a possible product, water as a possible electrolyte and / or sulfuric acid or potassium sulfate as a possible electrolyte additive.

The mixtures in FIGS. 14 and 15 were suitably adjusted by weighing. For Figure 16, the initial mixtures were adjusted by weighing, after which sulfuric acid was added Weighing gradually added. The conductivity was determined using a conventional conductivity sensor.

The results of the measurements are shown in FIGS. 14 to 16.

14 shows the measurements of mixtures of formic acid with K ₂ SO ₄ , the electrical conductivity being plotted against the mass fraction of K ₂ SO ₄ in% by weight.

For the measurement results in FIG. 15, mixtures of formic acid and sulfuric acid were used, the x-axis here representing the mass fraction of sulfuric acid in% by weight.

For the measurements in FIG. 16, various mixtures of water and formic acid were prepared, the mixing ratios [m / m] being given for the individual graphs. 100% water was also applied as a reference.

The mixtures and the water were mixed with sulfuric acid and the mass fraction of sulfuric acid in% by weight in relation to the mixtures was plotted on the x-axis.

FIGS. 14 to 16 show that by adding salt or acid, the poor conductivity of formic acid - a possible intermediate in the present process for the production of CO - can be increased, so that it can also assume technically relevant values.

CO2 can be reduced electrochemically to CO in one step. However, it is disadvantageous that the hydroxide ions formed with excess CO2 form hydrogen carbonate. This reaction is the cause of an energy (better exergy) loss of the invested electrical energy. Here, 28% of the electrical energy used is converted into heat. This loss can be synergistically reduced to approx. 16% (280 mV) by combining an electrochemical and a thermochemical step.

a. The electrochemical production of formic acid and / or formate from CO2

b. The thermochemical, for example acid catalyzed,

Cleavage of formic acid into the target product CO and H2O.

Preferred embodiments result since both processes can be combined without the formic acid having to be presented in pure form. The electrolyte volume simultaneously represents a storage volume for formic acid or CO. Acid or salt-like additives increase both the conductivity and they are control variables for the thermal release of the CO.

Claims

Claims

1. A method for producing CO from CO2 comprising electrolytic conversion of a starting material comprising CO2 to a mixture comprising formic acid and / or formate in a first electrolytic cell,

Removing the mixture comprising formic acid and / or formate,

Introducing the mixture comprising formic acid and / or formate into a first reactor, and

Releasing a product comprising CO from the mixture comprising formic acid and / or formate in the first reactor.

2. The method according to claim 1, wherein a, preferably aqueous, first electrolyte of the electrolytic conversion of the starting material comprising CO2 to a mixture comprising formic acid and / or formate comprises an acid and / or a formate salt and / or a sulfate salt, more preferably a liquid Acid.

3. The method according to claim 2, wherein at least one anion exchange membrane, preferably in a region of the first cathode, is present between a first cathode and a first anode of the first electrolytic cell.

4. The method according to any one of the preceding claims, wherein the first electrolytic cell between a first cathode and a first anode in a region of the first anode has a cation exchange membrane or a bipolar membrane.

5. The method according to any one of the preceding claims, wherein a cathode of the first electrolytic cell comprises a metal which is selected from Cu, Bi, Pb, Hg, In, Sn, Cd, TI, before Pb, Bi, Hg, In, Sn , Cd, TI, more preferably Pb, Bi.

6. The method according to any one of the preceding claims, wherein the mixture comprising formic acid and / or formate after removal from the first electrolytic cell and before introduction gene is stored in the first reactor in a first container.

7. The method according to any one of the preceding claims, wherein the content of formic acid and / or formate in the mixture comprising formic acid and / or formate after the electrolytic reaction of the educt comprising CO2 in a range of 0.5 wt.% Or more and 100 % By weight or less, preferred

1 wt% or more and 95 wt% or less, more preferably 5 wt% or more and 90 wt% or less.

8. The method according to any one of the preceding claims, wherein the release of CO from the mixture comprising formic acid and / or formate in the first reactor by dehydration, preferably by heating and / or heterocatalytic dehydration, takes place.

9. The method according to any one of the preceding claims, wherein the CO is further converted in a second electrolytic cell to at least one hydrocarbon, the reaction preferably taking place in the presence of a second, basic electrolyte.

10. Process for the electrolytic conversion of a starting material comprising CO to a mixture comprising at least one hydrocarbon, the reaction taking place in the presence of a basic electrolyte, preferably the anode Fe,

Includes Ni and / or NiFe.

11. Device for producing CO from CO2 comprising a first electrolytic cell comprising a first cathode and a first anode for the electrolytic conversion of a starting material comprising CO2 to a mixture comprising formic acid and / or formate, which is designed to form a starting material comprising CO2 to one To implement a mixture comprising formic acid and / or formate;

a first feed device for a starting material comprising CO2 to the first electrolytic cell, that with the first electrolytic cell is designed to supply an educt comprising CO2 of the first cathode;

a first discharge device for a mixture comprising formic acid and / or formate, which is connected to the first electrolytic cell in a region between the first cathode and the first anode and which is designed to produce a mixture comprising formic acid and / or formate from the first Dissipate electrolytic cell;

a first reactor for releasing a product comprising CO from the mixture comprising formic acid and / or formate, which is designed to release a product comprising CO from the mixture comprising formic acid and / or formate;

a second feed device for the mixture comprising formic acid and / or formate, which is connected to the first reactor and is designed to supply the mixture comprising formic acid and / or formate to the first reactor; and

a second discharge device for discharging the product comprising CO from the first reactor, which is designed to discharge the product comprising CO from the first reactor.

12. The apparatus of claim 11, wherein the first electrolytic cell has at least one anion exchange membrane between the first anode and the first cathode, preferably in a region of the first cathode.

13. The apparatus of claim 11 or 12, wherein the first electrolytic cell between the first cathode and the first anode in a region of the first anode has a cation exchange membrane or a bipolar membrane

14. Device according to one of claims 11 to 13, wherein the first cathode of the first electrolytic cell comprises a metal which is selected from Cu, Bi, Pb, Hg, In, Sn, Cd, TI, preferably Pb, Bi, Hg, In, Sn, Cd, TI, more preferably Pb.

15. The device according to one of claims 11 to 14, further comprising a first container for temporarily storing the mixture comprising formic acid and / or formate, which is arranged between the first discharge device and the first supply device and which is designed to comprise the mixture comprising formic acid and / or cache formate.