RU2393593C1 - Procedure for purification of air from carbon dioxide for alkaline hydrogen-air fuel elements - Google Patents

Abstract

FIELD: power engineering.

SUBSTANCE: invention refers to electro-chemical generators of current (ECG) on alkaline fuel elements (FE), particularly to auxiliary functional installations of FE maintenance, namely to installations for purification of air, used in FE as oxidant, from carbon dioxide. According to the invention, the procedure for purification of air from carbon dioxide for alkaline hydrogen-air fuel elements consists in purification of preliminary humidified air in electro-chemical de-carbonator, wherein CO₂ is chemically absorbed with solution of hydroxide of alkaline metal, while de-sorption of CO₂ is performed chemically from a porous catalysed electrode. An electro-chemical cell is used as de-carbonator where a cathode of alkaline fuel element functions as a negative electrode, while an anode of alkaline electrolytic cell functions as a positive electrode. De-carbonator is fed from am external current source of voltage 0.7… 1.48 V.

EFFECT: developing continuous inertia-free procedure of deep purification of air from carbon dioxide facilitating complete elimination of not-productive losses of hydrogen, while ensuring utilisation of ECG with alkaline fuel elements in any premises.

1 dwg, 1 ex

Description

The present invention relates to the field of electrochemical current generators (ECGs) on alkaline fuel cells (FCs), in particular to auxiliary functional devices for servicing FCs, and in particular to devices for purifying carbon dioxide from air used in FCs as an oxidizing agent.

Feeding a fuel cell with an alkaline electrolyte by atmospheric air is complicated by the fact that the carbon dioxide (CO ₂ ) contained in it, sometimes reaching up to 500 ppm, reacts with alkali to form alkali metal carbonates. As a result, the efficiency and life of the fuel cell are reduced both due to changes in the electrolyte composition and the formation of solid carbonate deposits, which impede the gas supply of the electrodes. In view of the foregoing, a deep purification of air from CO _{2 is} necessary.

A known method of removing carbon dioxide from air used as an oxidizing agent in a fuel cell (US Pat. alkali solution. Alkali absorbs carbon dioxide. After working out, the containers are removed from the device and the absorber is regenerated. The regeneration is carried out by calcining the granules at temperatures of 900-1400 ° C, during which the carbonates decompose with the removal of carbon dioxide. After calcining, the granules are hydrated to form alkali. The second method of regeneration of spent granules, which is claimed in this patent, is the interaction of the formed alkali metal carbonates with calcium oxide or barium hydroxide. In this case, insoluble calcium or barium carbonates are formed, which are filtered off, and alkali, which is re-impregnated with granules.

The disadvantage of this method is its discontinuity associated with the need for periodic regeneration. In addition, the claimed regeneration methods are characterized by increased energy intensity and complexity.

To some extent, these disadvantages were eliminated by using a method in which zeolites are used as regenerated carbon dioxide absorbers (US Pat. No. 6,273,939, class IPC B01D 53/04, priority date 10/20/1999). The depth of air purification from CO ₂ using zeolites reaches 1 ppm. The adsorption process is carried out at a pressure of from 10 ⁵ Pa to 10 ⁷ Pa (preferably from 3 · 10 ⁵ Pa to 6 · 10 ⁶ Pa). Desorption is carried out at pressures from 3 · 10 ⁵ Pa to 10 ⁴ Pa at temperatures from 50 to 250 ° C.

However, atmospheric moisture significantly reduces the adsorption capacity of zeolites for carbon dioxide, and for the complete regeneration of zeolites from both CO ₂ and water, a short-cycle adsorption method is used in which temperatures of 500-600 ° C are necessary for desorption. The disadvantage of this method is the significant energy consumption.

Also known is a method of removing carbon dioxide from air consumed in a fuel cell (Russian patent No. 2229759, class IPC H01M 8/06, B01D 53/56, priority date 11/05/2002), which consists in the fact that air is passed through an adsorber with an absorber carbon dioxide, then the sorbent is regenerated by heating. As an absorber, hydrated transition metal oxides, for example hydrated zirconium oxide, are used, which are regenerated by the air spent in the fuel cell at a temperature of 60-120 ° C. The heating of the air entering the regeneration is carried out until a relative humidity of 15 to 85% is reached.

According to the invention, a special system of valves with two adsorbers equipped with a carbon dioxide absorber is designed to ensure the continuity of the cleaning process by alternately switching the adsorbers to sorption or desorption. At the same time, this cleaning method has a number of significant drawbacks.

1. In the modes of switching the adsorber from the desorption mode to the sorption mode due to thermal inertia, the temperature of the sorbent remains high for some time (since before that it was regenerated by air at a temperature of 60-120 ° C), as a result, the required depth is not provided during this period of time air purification.

2. Used sorbent has a low sorption capacity when cleaning moist air, which also limits the scope of its application and use.

3. The device has significant weight and size characteristics, since a significant amount of adsorbent is required to ensure technically acceptable durations of adsorption and desorption cycles. In addition, a node is required for heating air during desorption and air flow switch valves with corresponding actuators.

As a prototype, a method was selected for purifying air from carbon dioxide in a hydrogen-air matrix fuel cell with an alkaline electrolyte (patent application of Russia according to IPC class H01M 8/04, H10M 2/14, state registration number 2008121405, priority date 05.27.2008 .). The method consists in the fact that before applying alkaline fuel cells to the battery, the air is preliminarily purified from CO ₂ in a separate unit, consisting of one or more alkaline hydrogen-air fuel cells (SHTE) and a humidifier. In SHTE, CO ₂ is chemically absorbed from the air by alkali metal hydroxide, and is desorbed electrochemically on a hydrogen electrode. The air is preliminarily humidified to prevent precipitation of alkali metal carbonates in the gas chambers of the fuel cells. Humidification is carried out by water vapor produced in the ECG. Water is heated to a temperature of 30 to 90 ° C. From the anode cavity, CO ₂ is carried out by periodic purges of hydrogen.

This method has a significant disadvantage, namely the removal of carbon dioxide by blowing hydrogen; this leads, firstly, to unproductive losses of hydrogen, and secondly, the field of application of ECG is sharply limited. It cannot be used in ordinary rooms due to the explosiveness of the air-hydrogen mixture.

The objective of the proposed technical solution is to create a continuous inertia-free method of deep purification of air from carbon dioxide, completely eliminating unproductive losses of hydrogen and opening the possibility of using ECG with alkaline fuel cells in any room.

The specified technical result is achieved by the fact that before the alkaline fuel cells are supplied to the battery (as in the prototype), the air is preliminarily purified from CO ₂ in a decarbonizer, in which CO _{2 is} chemically absorbed by an alkali metal hydroxide solution and is desorbed electrochemically from a porous catalyzed electrode. Before being fed to the decarbonizer, the air is humidified to prevent the precipitation of alkali metal carbonates in the decarbonizer. Humidification is carried out by water vapor produced in the ECG. Water is heated to a temperature of 30 to 90 ° C.

Unlike the prototype, in addition, the technical result is achieved in that the decarbonizer is not a fuel cell, but an electrochemical cell, sometimes called an oxygen pump. Its negative electrode (to which “-” is supplied from an external current source) is the cathode of the alkaline fuel cell, and the positive electrode is the anode of the alkaline cell. The decarbonizer may include one or more electrochemical cells. At the negative electrode of the decarbonizer, CO ₂ is absorbed and oxygen is electroreduced by the reactions:

2KOH + CO ₂ → K ₂ CO ₃ + H ₂ O

O ₂ + 2H ₂ O + 4e → 4OH ^- ,

and on the positive electrode - the evolution of oxygen and CO ₂ according to the reactions:

2OH ^- -2e → 1 / 2O ₂ + H ₂ O

C0 ₃ ^2- -2e → CO ₂ + 1 / 2O _2.

The raw air enters the decarbonizer from the gas diffusion catalyzed electrode of the fuel cell, where CO ₂ is absorbed.

In contrast to the prototype, in the proposed technical solution, CO ₂ is released at the cathode of the electrolyzer, from where it is removed by blowing off the exhaust air leaving the ECG (oxygen depleted).

The work of the proposed decarbonizer is carried out by an external current source. It was experimentally established that the optimal voltage for electrochemical reactions lies in the range 0.7 ... 1.48 V. At voltages less than 0.7 V, the carbon dioxide evolution proceeds unacceptably slowly, and at voltages greater than 1.48 V, water electrolysis begins with unproductive energy and hydrogen emissions.

The invention is illustrated by the diagram shown in the drawing, and a description of its operation by the claimed method. The CO ₂ air purification unit (1) contains a humidifier (2) and a decarbonizer (3) connected to a direct current source (4). Air (5) to the humidifier (2) is supplied by a compressor or fan (6). From the humidifier (2), air enters the cathode cavity of the decarbonizer (3), where CO _{2 is} chemically absorbed, and is simultaneously electrochemically released in the anode cavity of the same decarbonizer (3). The air (7) purified from CO _{2 is} used as an oxidizing agent in the fuel cell battery (8) of the electrochemical generator (9). Hydrogen (11) circulates through the ECG (9) using a compressor (10), which evaporates the water synthesized during the current generation process. The vapor-hydrogen gas mixture enters the dehumidifier (12), where the water condenses. Condensed water (13) is supplied to the humidifier (2), and the air (14) exhausted in the ECG (9) is supplied to the anode cavity of the decarbonizer (3) and blows out the carbon dioxide released from it (15).

An example implementation of the proposed technical solution.

Decarbonizers with a thickness of 1.5 mm and an area of 176 cm ² each with a matrix alkaline electrolyte and catalyzed gas diffusion electrodes were assembled in a six-cell battery with parallel gas switching and serial current switching. As an electrolyte, an aqueous solution of potassium hydroxide with a concentration of 12 g · equiv / l was used. The humidifier had a cylindrical shape, its volume was 100 cm ³ .

With an air flow rate of 10 l / min, a humidifier temperature of 50 ° C, a battery temperature, decarbonizers of 70 ° C and a voltage of 6.00 V applied to the battery (average 1.00 V per cell), the CO ₂ content in the air at the outlet of the cleaning device during the entire operating time (250 hours) did not exceed 2 ... 5 ppm, and after eight hours of operation, the content of CO ₂ in the air leaving the anode cavity of the decarbonizer battery was equal to the content of carbon dioxide in the ambient air, i.e. the accumulation of carbonates dissolved in the electrolyte reached a stationary level, and all carbon dioxide entering the cathode cavity was released in the anode cavity.

Thus, the use of the proposed technical solution eliminates unproductive losses of hydrogen, provides longer operation of alkaline hydrogen-air fuel cells and, as a result, increases the duration of the BFC of the electrochemical generator. In addition, the inventive method allows the use of ECG with alkaline fuel cells in any room. The application of the proposed method does not require any removable or replaceable adsorbents, and this leads to a decrease in the overall dimensions of the electrochemical generator as a whole, which is of great importance for its widespread use as an alternative energy source in such branches of technology as, for example, automobile manufacturing, and in space technology.

Claims (1)

A method for purifying air of carbon dioxide for alkaline hydrogen-air fuel cells, comprising purifying pre-moistened air in an electrochemical decarbonizer, in which CO _{2 is} chemically absorbed with an alkali metal hydroxide solution, and CO ₂ is desorbed electrochemically from a porous catalyzed electrode, characterized in that as a decarbonizer, an electrochemical cell is used, the negative electrode of which is the cathode of an alkaline fuel cell, and spruce - the anode of an alkaline electrolyzer; the decarbonizer is powered by an external current source of 0.7 ... 1.48 V.