This application claims priority from Japanese application serial No. 2004-343249, filed on Nov. 29, 2004, the content of which is hereby incorporated by reference into this application.
The present invention relates to a method, an apparatus and a catalyst for catalytically decomposing water at low temperatures to produce hydrogen and oxygen.
Nowadays a development of clean energy is urged from the view points of exhaustion of fossil fuels and preservation of the global environment. Utilization of hydrogen energy is one of typical examples of clean energy among the resources; however, hydrogen hardly exists by itself on the earth. Accordingly, a technology for supply hydrogen is the key for development of hydrogen energy. At present, many investigations of hydrogen production have been made; among them, a technology for producing hydrogen from water that is almost unexhaustible on the earth is particularly important. Electrolysis, steam reforming using fossil fuel, light-energy utilization using semiconductor photoelectron-chemical reaction, chemical reaction cycle using exhaust gas from high temperature furnaces, etc have been attempted.
In patent document No. 1 (WO 2004/020330), there is disclosed a catalytic decomposition of water at 130° C. in the presence of a catalyst carrying an alkali metal oxide and an alkaline earth metal oxide and a water electrolysis method using the catalyst.
In patent document Nos. 2, 3 (Japanese patent laid-open No. 10-263397 and Japanese patent laid-open No. 11-171501), there is disclosed a water electrolysis method using a natural zeolite at high temperature.
In general, a conversion temperature at which a reaction free energy for thermally decomposing water into hydrogen and oxygen changes a positive value to a negative value must exceed at several thousands degrees Celsius. Accordingly, there is no solution to produce hydrogen by a pure thermal decomposition of water.
The present inventors have discovered that if the reaction free energy change from the positive value to the negative value takes place at a temperature much lower than several thousands degrees Celsius, hydrogen may be produced from water.
The thermal decomposition equilibrium of water is expressed as follows.
H2O←→H2+½ O2 (1)
In the equilibrium equation, a temperature condition under which the Gibbs free energy change ΔG changes into negative is as high as about 4000 degrees Celsius. Therefore, a direct thermal decomposition of water to produce hydrogen is not practical. The temperature condition where ΔG becomes negative is one under which the reaction equilibrium is the hydrogen generation reaction where hydrogen is produced from water as an initial reaction species. This equilibrium is considered as a necessary reaction condition by water decomposition for continuously supplying hydrogen.
Since the reaction proceeds backward if ΔG is positive, efficiency of decomposition reaction is bad and the reaction is unstable; thus the industrial production process will not be formulated. Accordingly, a technology that makes the Gibbs free energy ΔG becomes negative at several hundreds degrees Celsius is necessary for a clean energy technology using hydrogen. The above mentioned patent documents do not disclose the formation of micro cells comprising a catalyst of a solid acid catalyst and a solid base catalyst.
It is an object of the present invention to provide a method of thermal decomposition at relatively low temperatures to produce hydrogen and oxygen and an apparatus and a composite catalyst for practicing the method.
The present invention is featured by a water decomposition method wherein heated water is in contact with a composite catalyst, which comprises a mixture of a solid acid catalyst and a solid base catalyst. In a typical embodiment, the composite catalyst comprises 35 to 65% by weight of the solid acid catalyst and the solid base catalyst being balance. Preferably, the solid acid catalyst and the solid base catalyst in the composite catalyst have such a pH difference that a (water/oxygen redox) potential is substantially equal to a (water/hydrogen redox) potential, the potentials being given by the water potential-pH diagram at a given temperature. Water of a temperature higher than the given temperature such that the temperature exceeds the pH difference is contacted with the composite catalyst.
One of the embodiments of the present invention provides a method of catalytically decomposing water in a reaction vessel wherein a composite catalyst comprising a solid acid catalyst and a solid base catalyst is divided into several segments each being separated by means of ion-permeable membranes. The method comprises contacting water or steam with the composite catalyst at a temperature of 130° C. or higher, while applying a potential between the electrodes contacted with the segments of the catalysts.
Preferable solid acid catalysts and the solid base catalysts are particles having 1 to 50 μm. The main component of the solid acid catalysts is silicon acids, and the main component of the solid base catalysts is at least one of alkali metal compounds and alkaline earth metal compounds. Preferable silicon oxides are alumino-silicates. The solid base catalyst contains at least one oxide of K, Mg, and Ca. The temperature of water is 130° C. or higher.
The present invention provides a water decomposition apparatus comprising a reactor filled with a composite catalyst comprising a solid acid catalyst and a solid base catalyst being balance having a particle size of 1 to 50 μm and a means for supply water to the reactor. The composite catalyst comprises 35 to 65% by weight of the solid acid catalyst and the solid base catalyst. The composite catalyst has a pH difference, wherein a (H2O/O2 redox) potential is equal to a (H2O/H2 redox) potential at a given temperature, the potentials being given by the water potential—pH diagram at a given temperature. The temperature for water decomposition at which water is contacted with the catalyst should be such that the temperature exceeds the pH difference.
The present invention further provides a water decomposition apparatus comprising a reactor in which the composite catalyst comprising the solid acid catalyst and the solid base catalyst being divided into segments each being separated by one or more of ion permeable membranes, a positive electrode disposed at one face of the segment and a negative electrode disposed at the other face of the segment.
The apparatus may be provided with a heater for heating water; the water may be heated separately. The heated water may be cooled with a cooler after the reactor. The water that flows out from the reactor may be recycled to the reactor without being cooled. The apparatus may be provided with a separator for separating hydrogen from oxygen.
The present invention also provides a composite catalyst for water decomposition, which comprises a solid acid catalyst and a solid base catalyst in an amount of 35 to 65% by weight.
The present invention spontaneously provides a method of decomposing water wherein water or steam is contacted with a composite catalyst comprising a solid acid catalyst and a solid base catalyst at a temperature where the Gibbs free energy change ΔG is negative.
The water decomposition reaction proceeds from the left side to the right side of the equation (1) under such a condition that the ΔG is negative at a temperature of several hundreds when water is contacted with the composite catalyst.
When the solid acid catalyst and the solid base catalyst contact, micro cells comprising certain pH values at the positions of the respective micro-cells are formed at the contact points of the solid acid catalyst and the solid base catalyst, where protons H+ accept electrons to form hydrogen in accordance with the equation (3). When the potential of the cathode reaction is maintained at a potential higher than the anode reaction potential of the equation (4) where OH− ions release electrons. The driving force of widening the pH difference is the potential difference between the solid acid catalyst and the solid base catalyst. When the temperature of water to be decomposed is increased whereby the Gibbs energy change becomes negative, the decomposition of water takes place at several hundreds.
Water is in the dissociation equilibrium state represented by the equation (2). The product of protons H+ and hydroxy ions OH− is [H+][OH−]=10−14 (mol/L)2. Accordingly, a pH value −log[H+] of neutral water is 7.0.
Protons and hydroxyl ions have redox equilibriums with hydrogen as shown in the equation (2) and oxygen as shown in the equation (3), respectively. If (2)+(3)+(4) are summed, the overall reaction equation (1) is obtained.
H2O←→H++OH− (2)
2H++2e←→H2 (3)
OH−←→½O2+H++2e (4)
The redox potential of (3) should be higher than the redox potential of (4) so as to make the reaction (1) proceed spontaneously in the right hand direction. That is, the potential for receiving electrons at (3) should be higher than the potential for releasing electrons at (4). Electrons having negative charge or in the lower energy level move spontaneously towards the direction where the potential is high, do not move in the opposite direction. When the micro cells are formed, the reactions proceed spontaneously as in the discharge reaction in the cells to attain the ΔG<0. The relationship is understood from the equation (5) below.
ΔG=−nFΔE (5)
In the above, n is the number of reaction electrons, F is Faraday constant and ΔE is a single polar potential difference between the cathode reaction (electron acceptor) and anode reaction (electron donor). Since ΔE is positive, ΔG will not be negative unless the potential of the cathode reaction is higher than the potential of the anode.
In the process of water decomposition, the cathode reaction is represented by (3) and the anode reaction is represented by (4). When the pH values at 25° C., the potential of (3) is lower than the potential of (4) by 1.23 V. Therefore, the ΔG is a large positive value at 25° C.
Single electrode potentials at the cathode reaction and the anode reaction are determined by Nernst equation (6).
E=Eo+(2.303 RT/nF)log(activity of oxidized species)/(activity of reduced species) (6)
In the above, R is the gas constant, Eo is the standard single electrode potential when the activity of oxidized species and the activity of reduced species is 1.
According to the equation (6), the pH dependency of the equations (3) and (4) at 25° C. is E/pH=−60 mV. In the electrochemical potential, the standard hydrogen electrode (SHE) potential of the hydrogen electrode reaction represented by the equation (3) is defined as zero V. At 25° C., the standard electrode potential is 1.23 V vs. SHE.
Accordingly, the ΔpH difference to attain the same single electrode potentials for the equations (3) and (4) is calculated by (1.23/0.06); ΔpH is 20.5. At 200° C., since the coefficient of the logarithmic term (2.303 RT/nF) contains temperature term T, the absolute values of the pH dependency of the equations (3) and (4) of the single electrode potential becomes large, i.e. E/pH=−94 mV. The difference between the standard electrode potential of (3) and of (4) becomes smaller than that at 25° C.; under the pressured water condition, the potential decreases from 1.23 V to 1.09 V. See, D. D. Macdonald, M. Urquidi-Macdonald, Corrosion 46P. 380 (1990). Accordingly, the pH difference ΔpH necessary for making the single electrode potentials of (3) and (4) at 200° C. is 11.6. The logarithmic term in the Nernst equation is large the temperature increases. The higher the temperature, the narrower the pH difference for necessary to make the single electrode potentials of (3) and (4) equal becomes small.
When the pH difference is wider than the above mentioned range, the potential at the cathode reaction (3) is higher than that at the anode reaction (4). As a result, the Gibbs free energy change becomes negative according to the equation (5) thereby to establish the spontaneous reaction condition in the right hand direction. The solid acid points become cathode reaction points and the solid base points become anode reaction points so that a group of micro cells is formed to bring about spontaneous water decomposition reaction. As mentioned earlier, the pH difference at 25° C. is 20.5 or more, and water decomposition at 25° C. is very difficult. However, since at 200° C., the pH difference is less than 11.6, water decomposition becomes easier.
The present invention makes it possible to catalytically decompose water at a temperature as low as several hundreds degrees Celsius.
The present invention will be explained by reference to preferred embodiments, but the scope of the present invention will not limited to these embodiments.
In the potential—pH diagrams, the zone between the oxygen generation zone and the hydrogen generation zone shows an area where water exists stably. ΔE is obtained by subtracting the single electrode potential of the equation (4) from the single electrode potential of the equation (3).
In the diagrams, the cathode reaction is hydrogen generation reaction of (3) and the anode reaction is oxygen generation reaction of (4). The hydrogen generation reaction and the oxygen generation reaction accompany the water dissociation reaction of water shown by the equation (2), where protons accept electrons to form hydrogen and hydroxyl ions release electrons and protons to form oxygen. The overall reaction is expressed by the equation (1).
In
In evaluating ΔG in the equation (1) based on
In
At 25° C. the decomposition potential of water increase 1.23 V from 1.09 V at 200° C. (Corrosion 46P. 380 (1990)). Further, the potential change with respect to the pH change becomes smaller than that obtained from the potential-pH diagram at 200° C. Thus, a larger pH difference for attaining ΔG<0 is needed at 25° C. than that at 200° C.
The single electrode potential difference for hydrogen and oxygen reflects the temperature dependency of the standard electrode potential (Corrosion 46P. 380 (1990)). The temperature dependency on the pH dependency of the potential is caused by the temperature change of RT/nF constant in the Nernst equation.
As shown by the hatched areas in
A pH difference ΔpH for reversing the potentials of the hydrogen generation and the oxygen generation is 11.6 in
Accordingly, if the two kinds of catalysts form the condition of ΔpH>11.6 at the acid point and the base point (Overview of Chemistry, edited by Chemical Society of Japan, No. 34, Catalyst Design, pp 80-82 (1982), published by Gakkai Shuppan Center), micro cells or micro batteries are formed so that spontaneous decomposition of water proceeds. That is, the condition for forming the micro cells is ΔpH>11.6. Since ΔpH=11.6, ΔG=0. If ΔpH>11.6 is satisfied, ΔG becomes negative so that the reaction in (1) from the left hand to right hand proceeds.
At 100° C., a condition for ΔG<0 is ΔpH>15.8° C. Similarly, at 150° C., ΔpH>13.5, at 250° C., ΔpH>10.2 and at 300° C., ΔpH>8.96. Catalysts that have an acid point and a base point and satisfy the above conditions are necessary for the water decomposition.
An example of a combination of the solid acid catalyst and solid base catalyst that meets the ΔG<0 condition is as follows.
The solid acid catalyst; Al2O3.SiO2 containing 70% by weight of SiO2.
The solid base catalyst: at least one of alkali metal compounds and alkaline earth metal compounds such as CaO, MgO, K2O, etc.
Ceramic wool is an example of Al2O3.SiO2 composition. The ceramic wool comprises fibers of several microns in diameter. The solid acid catalyst material works as acid points and the solid base catalyst material works as base points. That is, the acid points function as a cathode and the base points function as an anode if the temperature of water is 200° C. or higher and ΔG<0 is satisfied.
In this embodiment, Al2O3.SiO2 containing 80% by weight of SiO2 as the solid acid catalyst and MgO or K2O as the solid base catalyst were used as a mixture of 1:1. The average particle size of the catalysts was 10 to 30 μm. The catalysts may be used not only in the form of particles, but in the form of pellets, grains, honeycombs, fibers, membranes, rods, etc. The water is supplied to the reactor from the bottom towards the top of the reactor. The reactor is heated to 200° C. or higher.
According to this embodiment, hydrogen and oxygen are produced at several hundreds Celsius without using electric energy.
The reactor is equipped with a heater connected to the electric heater power source 5. The reactor has a pressure vessel to withstand a high pressure. The adsorbed water in the catalysts is maintained in such a state that hydrogen is effectively produced by the micro-cells. The reactor is equipped with a pair of electrode for polarizing the micro-cells in the catalysts. As a result, the micro-cells decompose water to produce hydrogen and oxygen separately. The power source applies a potential between the electrodes of a voltage such as 1.0 volt, which is sufficient to polarize the micro-cells. Produced hydrogen and oxygen are discharged from the upper part of the reactor.
When the electric heater 98 is controlled to 130° C., water supplied at a rate of 2 mL/min goes up from the bottom thereof, while boiling. Part of the water comes from the top of the reactor. The platinum electrodes are connected with an electrometer having a resistivity of 1012 Ω or more to measure the potential. When the potential between the electrodes was measured, the one segment 7 exhibited a 0.05 volt higher potential than the other. Therefore, the Gibbs free energy ΔG for water decomposition given by the equation (5) is negative. That is, as is understood from
However, under the above conditions, generation of hydrogen was not confirmed. It is because that a potential necessary for decomposition of water was not created by the electric conductive resistance through the biscuit plate 10 shown in
The heating of the reaction vessel can be done by not only the electric heater, but also by heat from atomic power plants, chemical plants, thermal power plants, etc.
Number | Date | Country | Kind |
---|---|---|---|
2004-343249 | Nov 2004 | JP | national |
Number | Name | Date | Kind |
---|---|---|---|
3915896 | Oliver | Oct 1975 | A |
3939104 | Campbell et al. | Feb 1976 | A |
3944482 | Mitchell et al. | Mar 1976 | A |
3963830 | Kasai et al. | Jun 1976 | A |
4278650 | Dorrance | Jul 1981 | A |
4496662 | Chu | Jan 1985 | A |
4556749 | Hazbun | Dec 1985 | A |
4613724 | Debras et al. | Sep 1986 | A |
6037299 | Senn et al. | Mar 2000 | A |
6468499 | Balachandran et al. | Oct 2002 | B1 |
6582676 | Chaklader | Jun 2003 | B2 |
Number | Date | Country |
---|---|---|
10-263397 | Oct 1998 | JP |
11-171501 | Jun 1999 | JP |
WO 2004020330 | Mar 2004 | WO |
Number | Date | Country | |
---|---|---|---|
20060113197 A1 | Jun 2006 | US |