WO2021229963A1 - 電解システム及びその使用方法 - Google Patents
電解システム及びその使用方法 Download PDFInfo
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- WO2021229963A1 WO2021229963A1 PCT/JP2021/014830 JP2021014830W WO2021229963A1 WO 2021229963 A1 WO2021229963 A1 WO 2021229963A1 JP 2021014830 W JP2021014830 W JP 2021014830W WO 2021229963 A1 WO2021229963 A1 WO 2021229963A1
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- C—CHEMISTRY; METALLURGY
- C25—ELECTROLYTIC OR ELECTROPHORETIC PROCESSES; APPARATUS THEREFOR
- C25B—ELECTROLYTIC OR ELECTROPHORETIC PROCESSES FOR THE PRODUCTION OF COMPOUNDS OR NON-METALS; APPARATUS THEREFOR
- C25B15/00—Operating or servicing cells
- C25B15/02—Process control or regulation
- C25B15/023—Measuring, analysing or testing during electrolytic production
- C25B15/025—Measuring, analysing or testing during electrolytic production of electrolyte parameters
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- C—CHEMISTRY; METALLURGY
- C25—ELECTROLYTIC OR ELECTROPHORETIC PROCESSES; APPARATUS THEREFOR
- C25B—ELECTROLYTIC OR ELECTROPHORETIC PROCESSES FOR THE PRODUCTION OF COMPOUNDS OR NON-METALS; APPARATUS THEREFOR
- C25B1/00—Electrolytic production of inorganic compounds or non-metals
- C25B1/01—Products
- C25B1/02—Hydrogen or oxygen
- C25B1/04—Hydrogen or oxygen by electrolysis of water
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- C—CHEMISTRY; METALLURGY
- C25—ELECTROLYTIC OR ELECTROPHORETIC PROCESSES; APPARATUS THEREFOR
- C25B—ELECTROLYTIC OR ELECTROPHORETIC PROCESSES FOR THE PRODUCTION OF COMPOUNDS OR NON-METALS; APPARATUS THEREFOR
- C25B15/00—Operating or servicing cells
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- C—CHEMISTRY; METALLURGY
- C25—ELECTROLYTIC OR ELECTROPHORETIC PROCESSES; APPARATUS THEREFOR
- C25B—ELECTROLYTIC OR ELECTROPHORETIC PROCESSES FOR THE PRODUCTION OF COMPOUNDS OR NON-METALS; APPARATUS THEREFOR
- C25B15/00—Operating or servicing cells
- C25B15/02—Process control or regulation
- C25B15/023—Measuring, analysing or testing during electrolytic production
- C25B15/025—Measuring, analysing or testing during electrolytic production of electrolyte parameters
- C25B15/027—Temperature
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- C—CHEMISTRY; METALLURGY
- C25—ELECTROLYTIC OR ELECTROPHORETIC PROCESSES; APPARATUS THEREFOR
- C25B—ELECTROLYTIC OR ELECTROPHORETIC PROCESSES FOR THE PRODUCTION OF COMPOUNDS OR NON-METALS; APPARATUS THEREFOR
- C25B15/00—Operating or servicing cells
- C25B15/08—Supplying or removing reactants or electrolytes; Regeneration of electrolytes
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- C—CHEMISTRY; METALLURGY
- C25—ELECTROLYTIC OR ELECTROPHORETIC PROCESSES; APPARATUS THEREFOR
- C25B—ELECTROLYTIC OR ELECTROPHORETIC PROCESSES FOR THE PRODUCTION OF COMPOUNDS OR NON-METALS; APPARATUS THEREFOR
- C25B9/00—Cells or assemblies of cells; Constructional parts of cells; Assemblies of constructional parts, e.g. electrode-diaphragm assemblies; Process-related cell features
- C25B9/17—Cells comprising dimensionally-stable non-movable electrodes; Assemblies of constructional parts thereof
- C25B9/19—Cells comprising dimensionally-stable non-movable electrodes; Assemblies of constructional parts thereof with diaphragms
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- C—CHEMISTRY; METALLURGY
- C25—ELECTROLYTIC OR ELECTROPHORETIC PROCESSES; APPARATUS THEREFOR
- C25B—ELECTROLYTIC OR ELECTROPHORETIC PROCESSES FOR THE PRODUCTION OF COMPOUNDS OR NON-METALS; APPARATUS THEREFOR
- C25B9/00—Cells or assemblies of cells; Constructional parts of cells; Assemblies of constructional parts, e.g. electrode-diaphragm assemblies; Process-related cell features
- C25B9/17—Cells comprising dimensionally-stable non-movable electrodes; Assemblies of constructional parts thereof
- C25B9/19—Cells comprising dimensionally-stable non-movable electrodes; Assemblies of constructional parts thereof with diaphragms
- C25B9/23—Cells comprising dimensionally-stable non-movable electrodes; Assemblies of constructional parts thereof with diaphragms comprising ion-exchange membranes in or on which electrode material is embedded
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- C—CHEMISTRY; METALLURGY
- C25—ELECTROLYTIC OR ELECTROPHORETIC PROCESSES; APPARATUS THEREFOR
- C25B—ELECTROLYTIC OR ELECTROPHORETIC PROCESSES FOR THE PRODUCTION OF COMPOUNDS OR NON-METALS; APPARATUS THEREFOR
- C25B9/00—Cells or assemblies of cells; Constructional parts of cells; Assemblies of constructional parts, e.g. electrode-diaphragm assemblies; Process-related cell features
- C25B9/70—Assemblies comprising two or more cells
- C25B9/73—Assemblies comprising two or more cells of the filter-press type
- C25B9/77—Assemblies comprising two or more cells of the filter-press type having diaphragms
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- Y—GENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
- Y02—TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
- Y02E—REDUCTION OF GREENHOUSE GAS [GHG] EMISSIONS, RELATED TO ENERGY GENERATION, TRANSMISSION OR DISTRIBUTION
- Y02E60/00—Enabling technologies; Technologies with a potential or indirect contribution to GHG emissions mitigation
- Y02E60/30—Hydrogen technology
- Y02E60/36—Hydrogen production from non-carbon containing sources, e.g. by water electrolysis
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- Y—GENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
- Y02—TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
- Y02E—REDUCTION OF GREENHOUSE GAS [GHG] EMISSIONS, RELATED TO ENERGY GENERATION, TRANSMISSION OR DISTRIBUTION
- Y02E60/00—Enabling technologies; Technologies with a potential or indirect contribution to GHG emissions mitigation
- Y02E60/30—Hydrogen technology
- Y02E60/50—Fuel cells
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- Y—GENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
- Y02—TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
- Y02P—CLIMATE CHANGE MITIGATION TECHNOLOGIES IN THE PRODUCTION OR PROCESSING OF GOODS
- Y02P20/00—Technologies relating to chemical industry
- Y02P20/10—Process efficiency
- Y02P20/133—Renewable energy sources, e.g. sunlight
Definitions
- the present invention relates to an electrolytic system and a method of using the same.
- alkaline water electrolysis in which hydrogen gas is generated from the cathode and oxygen gas is generated from the anode is known.
- an electrolytic cell for alkaline water electrolysis for example, an electrolytic cell in which a gas phase portion is provided on the discharge side of the electrolytic cell to prevent the generation of leakage current through the outlet of the electrolytic cell is known (Patent Document 1).
- renewable energy has the property that its output is highly variable because its output depends on climatic conditions. Therefore, it is not always possible to transport the electric power obtained from power generation by renewable energy to the general electric power system, and there are concerns about social impacts such as imbalance of electric power supply and demand and destabilization of the electric power system. There is. Therefore, research is being conducted to replace the electric power generated from renewable energy with a form that can be stored and transported.
- alkaline water electrolysis As a method of electrolysis of water, there are solid polymer type water electrolysis method, high temperature steam electrolysis method, alkaline water electrolysis method, etc., but they have been industrialized for more than several decades and can be carried out on a large scale. Alkaline water electrolysis is considered to be one of the most promising ones because it is cheaper than other water electrolysis systems. However, in order to adapt alkaline water electrolysis as a means for storing and transporting energy in the future, as described above, it is possible to efficiently and stably use electric power with large fluctuations in output to perform water electrolysis. It is necessary to solve various problems of electrolytic cells and devices for alkaline water electrolysis.
- the structure of the electrolytic cell in order to solve the problem of improving the power intensity of hydrogen production by keeping the electrolytic voltage low in alkaline water electrolysis, the structure of the electrolytic cell, in particular, substantially eliminates the gap between the diaphragm and the electrode. It is well known that it is effective to adopt a structure called a zero gap structure (see Patent Documents 1 and 2).
- a zero gap structure In the zero gap structure, the generated gas is quickly released to the side opposite to the diaphragm side of the electrode through the pores of the electrode, thereby reducing the distance between the electrodes and suppressing the generation of gas pools in the vicinity of the electrodes as much as possible for electrolysis. The voltage is suppressed low.
- the zero gap structure is extremely effective in suppressing the electrolytic voltage, and is used in various electrolytic devices.
- the electrolysis system may stop supplying power due to maintenance or the like. Since the power supply is stopped for a long period of time, the current situation is that electrolytic systems in recent years are also required to respond when restarting after the power supply is stopped.
- Patent Document 1 aims to prevent the generation of leakage current during operation when the electrolytic cell is energized, and does not describe at all when the energization is stopped and when the energization is restarted.
- an object of the present invention is to prevent the gas generated during operation from being mixed when the power supply is stopped.
- an object of the present invention (I) is to suppress mixing of gas generated during operation when the power supply is stopped, and to shorten the time required for restarting after the power supply is stopped.
- the electrolytic device performs the electrolytic operation of the electrolytic solution by using a variable power source such as sunlight or wind power, and when the variable power source weakens or stops, the electrolytic operation is stopped and the electrolytic cell is operated.
- the gas generated during the operation remains as a gas layer together with the electrolytic solution during the electrolytic operation.
- a part (both sides) of the diaphragm dividing the electrode chamber into the anode chamber and the cathode chamber was exposed to the gas layer existing in each electrode chamber.
- the gas in each electrode chamber may slightly permeate the diaphragm and diffuse into each electrode chamber, for example, the hydrogen concentration in oxygen in the anode chamber or the hydrogen concentration in the cathode chamber. There was a risk that the oxygen concentration in hydrogen would increase locally.
- an object of the present invention (II) is to provide an operation method of an electrolytic device capable of suppressing the diffusion and mixing of gas between each electrode chamber through a diaphragm when electrolysis is stopped.
- the present invention is as follows.
- the invention described in [1] to [12] may be referred to as the present invention (I)
- the invention described in [13] to [17] may be referred to as the present invention (II).
- An electrolytic cell containing an electrolytic cell in which an anode and a cathode are overlapped with each other across a diaphragm, and a liquid level height for adjusting the liquid level of the electrolytic cell in the electrolytic cell, which operates when energization of the electrolytic cell is stopped.
- An electrolytic system characterized by including control means.
- [10] The means for injecting the electrolytic solution into the electrolytic cell by a liquid feeding pump when the liquid level of the electrolytic solution is located vertically below the upper end of the uncoated end of the diaphragm.
- the electrolytic system according to [9].
- [11] The electrolysis system according to any one of [1] to [10], which is used for alkaline water electrolysis.
- [12] The method of using the electrolytic system according to any one of [1] to [11].
- [13] A method of operating an electrolytic device including an anode chamber having an anode and a cathode chamber having a cathode, which are mutually partitioned by a diaphragm.
- the energization step in which the electrolytic solution in the anode chamber and the cathode chamber is electrolyzed, and It has a stop step in which electrolysis of the electrolytic solution in the anode chamber and the cathode chamber is stopped.
- a method for operating an electrolytic apparatus wherein in the stopping step, the liquid level of the electrolytic solution in the anode chamber and / or the cathode chamber is located vertically above the upper end of the uncoated end of the diaphragm.
- the respective liquid levels are monitored by a liquid level gauge that measures the liquid levels of the electrolytic solution in the anode chamber and the cathode chamber, and the liquid levels in the anode chamber and the cathode chamber are the diaphragms.
- the electrolytic solution is injected into the anode chamber and / or the cathode chamber by a liquid feed pump, and the liquid surface of the anode chamber and / or the cathode chamber is set to the diaphragm.
- the operation method of the electrolytic apparatus according to [13] which is located vertically above the upper end of the uncoated top of the above.
- the liquid feed pump is continuously or intermittently operated to position the liquid level of the anode chamber and / or the cathode chamber vertically above the uncoated upper end of the diaphragm, [13] or [14] The operation method of the electrolytic device according to [14].
- the electrolytic device has a storage tank for storing the electrolytic solution, which is located vertically above the electrolytic cell of the electrolytic cell.
- the electrolytic solution in the storage tank is injected into the anode chamber and / or the cathode chamber by using gravity, and the liquid surface of the anode chamber and / or the cathode chamber is not coated with the diaphragm.
- the electrolysis system of the present invention has the above configuration, it is possible to suppress mixing of gas generated during operation when the power supply is stopped.
- (A) is an example in which the liquid level height is adjusted by the liquid level height controlling means
- (b) is an example in which the liquid level height is not adjusted.
- FIG. 7 is a schematic cross-sectional view showing a modified example of the cathode chamber shown in FIG. 7 in a cross section in a plane along a vertical direction and a direction perpendicular to the cathode. This is the result of Example 1. This is the result of Example 2.
- the present embodiment a mode for carrying out the present invention (hereinafter referred to as “the present embodiment”) will be described in detail.
- the present invention is not limited to the following embodiments, and can be variously modified and implemented within the scope of the gist thereof.
- the embodiment of the present invention (I) may be referred to as the present embodiment (I)
- the embodiment of the present invention (II) may be referred to as the present embodiment (II).
- the electrolytic cell of the present embodiment (I) is an electrolytic cell including an electrolytic cell in which an anode and a cathode are overlapped with each other across a diaphragm, and an electrolytic cell in the electrolytic cell that operates when energization of the electrolytic cell is stopped. Includes a liquid level height control means for adjusting the liquid level height of the water level.
- the electrolytic system (electrolyzer) used in the operation method of the present embodiment (II) includes an anode chamber having an anode and a cathode chamber having a cathode, which are mutually partitioned by a diaphragm, and electrolyzes in the anode chamber and the cathode chamber. When the electrolysis of the liquid is stopped, the liquid level of the electrolytic solution in the anode chamber and / or the cathode chamber is located vertically above the upper end of the uncoated end of the diaphragm.
- FIG. 1 is a schematic view showing an example of the electrolytic system of the present embodiment.
- the electrolysis system 70 includes an electrolytic cell 50. Further, the liquid level height control means 30 may be included. Further, a supply power supply 74, a liquid feed pump 71 for circulating the electrolytic solution, a gas-liquid separation tank 72 for separating the electrolytic solution and a gas (for example, hydrogen, oxygen, etc.) (anodic gas separation tank 72a, cathode gas, etc.) Separation tank 72c), a water replenisher 73 for replenishing water consumed by electrolysis, a concentration meter, a flow meter 77, a pressure gauge 78, a heat exchanger 79, a pipe 81, a pressure control valve 80 and the like may be included.
- a supply power supply 74 a liquid feed pump 71 for circulating the electrolytic solution, a gas-liquid separation tank 72 for separating the electrolytic solution and a gas (for example, hydrogen, oxygen, etc.) (anodic gas separation tank
- liquid level height control means 30 is an electrolytic solution circulation pump
- a liquid feed pump 71 also having a function as a liquid level height control means may be used, or a pump different from the liquid feed pump 71 may be used. You may use it.
- the arrow in FIG. 1 indicates the direction in which the electrolytic solution or gas flows.
- the electrolytic cell may be an electrolytic cell including an electrolytic cell in which an anode and a cathode are overlapped with each other across a diaphragm.
- the electrolytic cell may include an anode chamber having an anode partitioned by a diaphragm and a cathode chamber having a cathode.
- the electrolytic cell may be a unipolar type or a multipolar type in which at least one electrode element is connected.
- the multi-pole type is one of the methods of connecting a large number of electrode elements in series to connect to a power source, and a plurality of multi-pole elements 60 having an anode 2a on one side and a cathode 2c on one side are connected to a diaphragm 4.
- the electrolytic cell for example, in two adjacent elements (for example, two adjacent elements of the anode terminal element 51a, the multipolar element 60, and the cathode terminal element 51c), one of the two adjacent elements sandwiches the diaphragm 4.
- An electrolytic cell having at least one structure in which the anode 2a of the element of No. 1 and the cathode 2c of the other element are overlapped and arranged side by side can be mentioned.
- the diaphragm 4 is preferably provided between all two adjacent elements in the electrolytic cell.
- the multi-pole electrolytic cell has a feature that the current of a power source can be reduced, and a large amount of a compound, a predetermined substance, or the like can be produced in a short time by electrolysis. If the output of the power supply equipment is the same, low current and high voltage are cheaper and more compact, so industrially, the multi-pole type is preferable to the single-pole type.
- FIG. 2 shows an example of the electrolytic cell 50.
- the electrolytic cell 50 shown in FIG. 2 is a multi-pole electrolytic cell.
- the multi-pole electrolytic cell may be configured by laminating a required number of elements 60 (for example, a multi-pole element).
- the fast head 51h, the insulating plate 51i, and the anode terminal element 51a are arranged in this order from one end, and further, the anode side gasket portion 7, the diaphragm 4, the cathode side gasket portion 7, and the element 60 (for example, a multi-pole type). Elements) are arranged side by side in this order.
- the element 60 is arranged so that the cathode 2c faces the anode terminal element 51a side.
- the anode-side gasket portion 7 to the element 60 are repeatedly arranged as many times as necessary for the design production amount. After repeatedly arranging the anode side gasket portion 7 to the element 60 as many times as necessary, the anode side gasket portion 7, the diaphragm 4, and the cathode side gasket portion 7 are arranged side by side again, and finally, the cathode terminal element 51c, the insulating plate 51i, and the like. Loose heads 51g are arranged in this order.
- the electrolytic cell 50 is integrated by tightening the entire electrolytic cell 50 by a tightening means such as a tie rod method 51r (see FIG. 2) or a hydraulic cylinder method.
- the element 60 includes an anode 2a, a cathode 2c, a partition wall 1 that separates the anode 2a and the cathode 2c, and an outer frame 3 that borders the partition wall 1.
- the partition wall 1 may have conductivity, and the outer frame 3 may be provided along the outer edge of the partition wall 1 so as to surround the partition wall 1.
- the elements 60 are overlapped with the diaphragm 4 interposed therebetween.
- the arrangement constituting the electrolytic cell can be arbitrarily selected from the anode 2a side or the cathode 2c side, and is not limited to the above-mentioned order.
- a bipolar electrolytic cell including a bipolar element or the like may be described, but the present invention is not limited to the bipolar electrolytic cell.
- the element 60 is arranged between the anode terminal element 51a and the cathode terminal element 51c.
- the diaphragm 4 is arranged between the anode terminal element 51a and the element 60, between the elements 60 adjacent to each other, and between the element 60 and the cathode terminal element 51c.
- the element 60 may be used so that the given direction D1 along the partition wall 1 is usually in the vertical direction, and specifically, as shown in FIGS. 5 and 6.
- the plan view shape of the partition wall 1 is rectangular, it may be used so that the given direction D1 along the partition wall 1 is in the same direction as the direction of one set of the two sets of opposite sides (the direction is the same as the direction of one set of sides. See FIGS. 5 and 6).
- the partition wall 1, the outer frame 3, the diaphragm 4, and the gasket 7 define an electrode chamber 5 through which the electrolytic solution passes (FIG. 3).
- the rectangular parallelepiped partition wall 1 and the rectangular diaphragm 4 are arranged in parallel, and the rectangular parallelepiped outer frame 3 partition wall 1 provided at the edge of the partition wall 1 is provided. Since the inner surface on the side is perpendicular to the partition wall 1, the shape of the electrode chamber 5 is rectangular parallelepiped.
- the portion between the two adjacent elements 60 between the partition walls 1 and the portion between the adjacent elements 60 and the terminal element 60 between the partition walls 1 are electrolyzed. It is referred to as cell 65 (FIG. 3).
- the electrolytic cell 50 includes an electrolytic cell 65 in which the anode 2a and the cathode 2c are overlapped with each other with the diaphragm 4 interposed therebetween.
- the electrolytic cell 65 preferably includes a partition wall 1 of one element, an anode chamber 5a, an anode 2a, and a diaphragm 4, and a cathode 2c, a cathode chamber 5c, and a partition wall 1 of the other bipolar element.
- a diaphragm 4 and a non-breathable membrane may be provided at a portion sandwiched between adjacent elements 60 and the like.
- the portion sandwiched between the anode 2a and the cathode 2c may be an ion-permeable diaphragm 4, and a non-breathable membrane that does not allow ions, gas, or an electrolytic solution to permeate may be used on the outer frame 3 side of the diaphragm. ..
- an anode liquid distribution tube for supplying the electrolytic solution to the anode chamber and a cathode liquid distribution tube for supplying the electrolytic solution to the cathode chamber may be provided on the lower side in the vertical direction of the electrode chamber, and the anode is provided on the upper side in the vertical direction.
- An anode liquid collecting tube 20ao for discharging the electrolytic solution from the chamber and a cathode liquid collecting tube 20co for discharging the electrolytic solution from the cathode chamber may be provided.
- the electrode chamber 5 may have an electrolytic solution inlet 5i for introducing the electrolytic solution into the electrode chamber 5 and an electrolytic solution outlet 5o for drawing out the electrolytic solution from the electrode chamber 5 at the boundary with the outer frame 3 (FIG. 5, 6).
- the anode chamber 5a is provided with an anode electrolytic solution inlet 5ai for introducing the electrolytic solution into the anode chamber 5a and an anode electrolytic solution outlet 5ao for leading out the electrolytic solution to be led out from the anode chamber 5a.
- the cathode chamber 5c may be provided with a cathode electrolytic solution inlet 5ci for introducing the electrolytic solution into the cathode chamber 5c and a cathode electrolytic solution outlet 5co for drawing out the electrolytic solution to be derived from the cathode chamber 5c.
- the anode chamber 5a and the cathode chamber 5c may be provided with an internal distributor for uniformly distributing the electrolytic solution in the electrolytic cell 50 and in the electrode surface.
- the electrode chamber 5 may be provided with a baffle plate having a function of limiting the flow of liquid inside the electrolytic cell 50.
- a Karman vortex is generated in order to equalize the concentration and temperature of the electrolytic solution inside the electrolytic cell 50 and to promote the defoaming of the gas adhering to the electrode 2 and the diaphragm 4. It may be provided with a protrusion for making.
- the electrode is a rectifying plate 6 (rib). ) May be provided (Fig. 3). Further, for the same reason, the current collector 2r is attached to the tip of the rectifying plate 6 (rib), and the conductive elastic body 2e is attached to the upper surface side of the current collector 2r, that is, the side opposite to the partition wall 1 side.
- the straightening vane 6 has substantially the same length as the height of the electrode chamber 5, is provided perpendicular to the partition wall 1, and has through holes at a predetermined pitch in the electrolytic solution passage direction. Have.
- the electrolytic system of the present embodiment preferably includes the liquid level height controlling means 30.
- the electrolytic cell in the energized state will be described with reference to FIG.
- the gas generated from the electrodes is stored vertically above the electrode chamber (FIG. 4A). If the energization stop state continues as it is, the temperature drops from the operating temperature and the electrolyte density increases, and as a result, the electrolyte level in the electrolytic cell gradually drops, and the interface between the gas and the electrolyte (liquid level 31, waterline).
- L) may be lower than the upper end of the diaphragm 4 that separates the anode and the cathode (the upper end of the diaphragm 4 exposed in the electrolytic cell, the uncoated upper end 4t) (FIG. 4 (b)).
- the rate at which the stored gas diffuses from one electrode chamber to the other electrode chamber is higher than the permeable diaphragm 4 where the liquid surface 31 (waterline length L) is exposed in the electrolytic chamber ( Compared with FIG. 4 (a)), when the diaphragm 4 is exposed, it becomes much faster (FIG. 4 (b)).
- the liquid level height control means 30 operates when energization is stopped, the liquid level 31 can be controlled vertically upward from the upper end of the diaphragm 4 exposed in the electrolytic chamber. Mixing of gas can be suppressed. Further, by keeping the liquid level high, the time required for restarting can be shortened.
- the liquid level height controlling means is preferably a means for controlling the liquid level height vertically upward from the uncoated upper end of the diaphragm. Controlling vertically upward from the upper end of the coating means not only that the liquid level height is always vertically above the upper end of the uncoated top, but also that the height of the liquid level is controlled after the height of the liquid level is lower than the upper end of the uncoated end. Includes recovery from the top of the uncovered area vertically above.
- the liquid level height controlling means 30 is based on the energization stop time, the electrolytic solution temperature, the liquid head pressure of the electrolytic solution, the electric resistance value, and the liquid level of the electrolytic solution in the electrolytic cell (for example, in the electrode chamber). It is preferable to adjust the liquid level according to at least one kind of trigger selected from the group.
- an instrument for measuring the trigger may be attached to the electrolysis system, and the liquid level may be adjusted based on the measured value of the instrument.
- it may include an apparatus for determining the amount of electrolytic solution to be injected into the electrolytic cell (for example, in the electrode chamber) according to the measured value.
- the trigger may be used alone or in combination of two or more.
- the trigger to be applied may be changed according to the time after the power supply is stopped.
- the liquid level height control means 30 is provided separately from the liquid feed pump 71 is described in FIG. 1, for example, one pump that can change the liquid feed amount according to the input from the trigger is used.
- a valve that adjusts the flow rate according to the input from the trigger may be used.
- the liquid level height controlling means 30 may adjust the amount of the electrolytic solution to be supplied to both electrode chambers so that the liquid levels on both sides of the cathode chamber and the anode chamber can be controlled, or may be supplied to one of the electrode chambers. Only the amount of the electrolytic solution to be used may be adjusted. Further, a uniform amount of the electrolytic solution may be injected into all the electrolytic cells (for example, all the electrode chambers), or the electrolytic solution to be injected into each electrode chamber may be adjusted according to the trigger value of each electrode chamber. ..
- the gas dissolved in the electrolytic solution may promote gas mixing, which is not preferable.
- the time for operating the liquid level height control means is preferably 20% or less, more preferably more than 0% and 20% or less, and 0. It is more preferably 1 to 5%.
- the upper end of the septum (for example, exposed to the electrolytic chamber) is exposed from the viewpoint of reducing the exposed area of the non-immersed diaphragm and suppressing the gas diffusion rate. It is more preferably a position within 100 mm vertically downward from the upper end of the septum and the upper end of the uncoated end 4t), further preferably a position within 10 mm from the upper end of the diaphragm, and particularly preferably the upper end of the diaphragm.
- the upper limit of the liquid level controlled by the liquid level height controlling means 30 is preferably the upper end of the electrode chamber. Further, from the viewpoint of further shortening the time required for restarting, the upper limit is the tube for discharging the electrolytic solution from the electrode chamber (for example, the internal header type anode liquid collecting tube 20ao, cathode liquid collecting tube 20co).
- the position is preferably filled with the electrolytic solution.
- the upper limit may be a position 10 mm from the vertical upper end of the liquid collecting tube, or the upper limit may be a position of 100 mm.
- the liquid level height controlling means uses a liquid feed pump to transfer the electrolytic solution into the electrolytic cell (for example,).
- the means for injecting into the electrode chamber where the liquid level height is lowered) is preferable.
- the liquid level height control means 30 operates the liquid level height control means when the lower limit of the liquid level height is reached, and the liquid level is controlled at once. It is preferable to raise the liquid level to the upper limit of the height.
- the upper limit and / lower limit of the liquid level may be changed according to the energization stop time, the electrolytic solution temperature, and the like.
- the energization stop time as the trigger may be the continuous cumulative time after the supply of electric power to the electrolytic cell is stopped.
- the energization stop time is preferably more than 0 hours and 240 hours or less, and more preferably more than 0 hours and 72 hours or less.
- the temperature of the electrolytic solution as the trigger may be the temperature of the electrolytic solution in the electrolytic cell or the temperature of the electrolytic solution discharged from the electrolytic cell.
- the electrolytic solution temperature it is preferable to operate the liquid level height control means 30 when the temperature is 10 ° C lower than the electrolytic solution temperature when the previous liquid level height control means 30 was operated, and the liquid level height control means 30 is preferably 5 ° C lower. It is more preferable to operate it at the time when it becomes.
- the operation may be performed when the temperature drops from the electrolytic solution temperature when the energization is stopped.
- the head pressure of the electrolytic solution as the trigger may be the head pressure of the electrolytic solution in each of the electrode chambers of the anode and the cathode.
- the head pressure may be measured by providing a pressure gauge or the like in the electrode chamber.
- the upper limit is preferably the liquid head pressure when the liquid level is at the upper end of the electrode chamber, and the lower limit is 100 mm vertically downward from the upper end of the diaphragm (for example, the upper end of the diaphragm exposed in the electrode chamber, the upper end of the uncoated end 4t).
- the liquid head pressure when the position is within 10 mm is more preferable, the liquid head pressure when the position is within 10 mm from the upper end of the diaphragm is further preferable, and the liquid head pressure when the position is within 10 mm is particularly preferable.
- Different upper and lower limits may be set for the anode chamber and the cathode chamber.
- the electric resistance value as the trigger may be the electric resistance value between the anode and the cathode of the electrolytic cell. Since the electrolytic solution has excellent electrical conductivity, the electric resistance value between the anode and the cathode decreases as the liquid level height increases. Therefore, the liquid level height control means 30 is operated when the electric resistance value reaches the upper limit. As the lower limit, the electric resistance value when the liquid level is at the upper end of the electrode chamber is preferable, and as the upper limit, the electric resistance value when the position is within 100 mm vertically downward from the upper end of the diaphragm is more preferable, and the position within 10 mm from the upper end of the diaphragm is more preferable. The electric resistance value at the time of is more preferable.
- the liquid level height controlling means may adjust the liquid level height according to the liquid level height of the electrolytic solution in the electrolytic cell.
- the liquid level height can be detected, for example, by providing a liquid sensor or the like in the electrode chamber.
- the liquid level control means preferably operates when the liquid level reaches the upper end of the diaphragm in the vertical direction, and operates when the liquid level is within 100 mm vertically downward from the upper end of the diaphragm. Is more preferable, and it is more preferable to operate when the position is within 10 mm from the upper end of the diaphragm, and it is particularly preferable to operate when the position is less than the upper end of the diaphragm.
- the gas generated by electrolysis is less likely to stay in the gap between the electrode and the diaphragm, the gas is less likely to be mixed, and the electrical resistance is lowered to enable an efficient electrolysis reaction.
- 4 may come into contact with the anode 2a and the cathode 2c to form the zero gap structure Z (FIG. 3).
- a gap is provided between the anode 2a, the diaphragm 4, and the cathode 2c, but it is preferable that there is no gap in the zero gap structure Z.
- the electrolytic cell when there is a gap between the diaphragm 4 and the anode 2a or the cathode 2c, a large amount of bubbles generated by the electrolysis stay in this portion in addition to the electrolytic solution, so that the electric resistance is very high. Become. In addition, the gas is likely to be mixed when the energization is stopped.
- the distance between the anode 2a and the cathode 2c hereinafter, also referred to as “polar distance” is made as small as possible so that it exists between the anode 2a and the cathode 2c. It is effective to eliminate the influence of the electrolytic solution and air bubbles.
- the anode 2a and the diaphragm 4 are in contact with each other over the entire surface of the electrode, and the cathode 2c and the diaphragm 4 are in contact with each other, or the distance between the electrodes is almost the same as the thickness of the diaphragm 4 over the entire surface of the electrode.
- a zero gap structure Z is adopted, which can be maintained in a state where there is almost no gap at a distance.
- a method for a method in which the anode 2a and the cathode 2c are completely smoothed and pressed so as to sandwich the diaphragm 4, or elasticity of a spring or the like between the electrode 2 and the partition wall 1 is used.
- a method of arranging a body and supporting the electrode 2 with this elastic body can be mentioned.
- a spring made of a conductive material may be attached to the partition wall 1, and an electrode 2 may be attached to the spring.
- a spring may be attached to the electrode rib attached to the partition wall 1, and the electrode 2 may be attached to the spring.
- the number of electrolytic cells 65 is preferably 50 to 500, more preferably 70 to 300.
- the electrolytic cell 50 preferably has 50 to 500 elements 60 (for example, a bipolar element), more preferably 70 to 300 elements 60, and particularly preferably 100 to 200 elements 60. ..
- the plurality of elements 60 are overlapped with each other sandwiching the diaphragm 4 in a state of being insulated from each other. By doing so, the elements 60 are isolated from each other.
- the state in which the plurality of elements 60 are mutually insulated is preferably in the state of being insulated between the outer frames 3 of the elements 60, for example, the gasket 7 arranged between the elements 60. This can be done by increasing the insulation of the. Further, the insulation here preferably means that the insulation resistance between the elements 60 is 1 M ⁇ or more.
- the electrolytic cell 50 has a cathode chamber 5c and an anode chamber 5a for each electrolytic cell 65.
- the electrolytic solution containing a sufficient amount of raw materials consumed by electrolysis to the cathode chamber 5c and the anode chamber 5a of each electrolytic cell 65.
- the header attached to the electrolytic cell there are typically an internal header type and an external header type, and any type may be adopted.
- the electrolytic cell 65 is connected to a supply / discharge pipe for an electrolytic solution called a header 10 which is common to the plurality of electrolytic cells 65.
- the anode liquid distribution tube is called an anode inlet header
- the cathode liquid distribution tube is called a cathode inlet header
- the anode liquid collecting tube is called an anode outlet header
- the cathode liquid collecting tube is called a cathode outlet header.
- the electrolytic cell 65 is connected to the liquid distribution pipe for each electrode and the liquid collection pipe for each electrode through a hose or the like.
- the internal header type refers to a type in which the electrolytic cell 50 and the header (tube for distributing or collecting the electrolytic solution) are integrated.
- the anode inlet header and the cathode inlet header are provided in the partition wall 1 and / or in the lower portion in the outer frame 3, and are provided so as to extend in the direction perpendicular to the partition wall 1.
- the anode outlet header and the cathode outlet header are provided in the partition wall 1 and / or in the upper portion in the outer frame 3, and are provided so as to extend in the direction perpendicular to the partition wall 1.
- a pipe in an electrode tank in which an anode liquid collecting pipe 20ao or a cathode liquid collecting pipe 20co provided in each electrode chamber is connected in a direction perpendicular to the partition wall 1 (left-right direction in FIG. 3). It may have a header that is discharged to the outside of the electrode tank through.
- a liquid distribution tube and a liquid collection tube may be provided in the electrode chamber (FIG. 4).
- the external header type refers to a type in which the electrolytic cell 50 and the header (the tube for distributing or collecting the electrolytic solution) are independent.
- the anode inlet header and the cathode inlet header, the anode outlet header and the cathode outlet header run independently with the electrolytic cell in the direction perpendicular to the current-carrying surface of the electrolytic cell. It will be provided.
- These headers and each element are connected by a hose. For example, in FIG.
- each anode liquid collecting tube 20ao or each cathode liquid collecting tube 20co provided in each electrode chamber extends to the outside of the electrolytic cell, and the anode electrolytic solution or the cathode electrolytic solution is applied outside the electrolytic cell. It may be put together in one pipe and sent to the gas-liquid separation tank.
- the electrolytic cell 50 may include a header 10 communicating with the electrode chamber 5 outside the outer frame 3 (see FIGS. 5 and 6).
- a header 10 for connecting a gas or an electrolytic solution to a pipe for distributing or collecting the electrolytic solution is attached to the electrolytic cell 50.
- the header 10 includes an inlet header for putting the electrolytic solution into the electrode chamber 5 and an outlet header for discharging gas and the electrolytic solution from the electrode chamber 5.
- an anode inlet header 10Oai for putting an electrolytic solution in the anode chamber 5a and a cathode inlet header 10Oci for putting the electrolytic solution in the cathode chamber 5c are provided below the outer frame 3 at the edge of the partition wall 1.
- an anode outlet header 10Oao for discharging the electrode liquid from the anode chamber 5a and a cathode outlet header 10Oco for discharging the electrolytic solution from the cathode chamber 5c are provided on the side of the outer frame 3 on the edge of the partition wall 1. .. Further, in one example, in the anode chamber 5a and the cathode chamber 5c, the inlet header and the outlet header are provided so as to face each other with the central portion of the electrode chamber 5 interposed therebetween.
- the electrolytic cell 50 of this example adopts an external header type in which the electrolytic cell 50 and the header 10 are independent.
- FIG. 6 shows an example of an electrolytic cell of an external header type electrolyzer in a plan view.
- the header 10 is attached with a conduit 20 which is a tube for collecting the gas or electrolytic solution distributed or collected in the header 10.
- the conduit 20 comprises a liquid distribution pipe communicating with the inlet header and a liquid collecting pipe communicating with the outlet header.
- an anode liquid distribution tube 20Oai communicating with the anode inlet header 10Oai and a cathode liquid distribution tube 20Oci communicating with the cathode inlet header 10Oci are provided below the outer frame 3 and similarly.
- an anode liquid collecting tube 20Oao communicating with the anode outlet header 10Oao and a cathode liquid collecting tube 20Oco communicating with the cathode outlet header 10Oco are provided.
- the inlet header and the outlet header are preferably provided at separate positions from the viewpoint of water electrolysis efficiency, and may be provided so as to face each other across the central portion of the electrode chamber 5.
- the plan view shape of the partition wall 1 is rectangular as shown in FIGS. 5 and 6, it is preferable that the partition wall 1 is provided so as to be symmetrical with respect to the center of the rectangle.
- the anode inlet header 10Oai, the cathode inlet header 10Oci, the anode outlet header 10Oao, and the cathode outlet header 10Oco are provided one by one in each electrode chamber 5, but the present invention is not limited thereto.
- a plurality of each may be provided in each electrode chamber 5.
- the anode liquid distribution tube 20Oai, the cathode liquid distribution tube 20Oci, the anode liquid collection tube 20Oao, and the cathode liquid collection tube 20Oco are provided one by one in each electrode chamber 5, but the present invention is not limited thereto. , May be shared in a plurality of electrode chambers 5.
- the rectangular parallelepiped partition wall 1 in the plan view and the rectangular diaphragm 4 in the plan view are arranged in parallel, and the partition wall 1 side of the rectangular parallelepiped outer frame provided at the end edge of the partition wall 1. Since the inner surface of the electrode chamber 5 is perpendicular to the partition wall 1, the shape of the electrode chamber 5 is a rectangular parallelepiped.
- the shape of the electrode chamber 5 is not limited to the rectangular parallelepiped of the illustrated example, but the shape of the partition wall 1 and the diaphragm 4 in a plan view, the inner surface of the outer frame 3 on the partition wall 1 side, and the partition wall 1. It may be appropriately deformed depending on the angle of formation and the like, and may have any shape as long as the effect of the present invention can be obtained.
- the positional relationship between the electrode chamber 5 and the header 10 is not particularly limited, and as shown in FIGS. 5 and 6, when the element 60 is used so that the given direction D1 along the partition wall 1 is in the vertical direction.
- the inlet header may be located below or to the side of the electrode chamber 5 (lower in the figure), and the exit header may be located above or to the side of the electrode chamber 5 (side in the figure).
- the liquid distribution pipe communicating with the inlet header is located below or to the side of the electrode chamber 5 (lower in the figure), and the liquid collecting pipe communicating with the outlet header is located with respect to the electrode chamber 5. It may be located above or to the side (side in the figure).
- the extending direction of the header 10 is not particularly limited.
- the extending direction of the conduit 20 is not particularly limited, but as in the example shown in FIGS. 5 and 6, from the viewpoint of facilitating the effect of the present invention, the liquid distribution pipe (anode liquid distribution pipe 20Oai, cathode).
- the liquid distribution pipe 20Oci) and the liquid collecting pipe (anode collecting pipe 20Oao, cathode liquid collecting pipe 20Oco) each preferably extend in a direction perpendicular to the partition wall 1, and all of the conduits 20 have. It is more preferable to extend in the direction perpendicular to the partition wall 1.
- the partition wall 1 A plurality of baffles 6 arranged in parallel with respect to a given direction D1 along the line may be provided.
- the material of the header is not particularly limited, but it is preferable to use a header that can sufficiently withstand the corrosiveness of the electrolytic solution used and the operating conditions such as pressure and temperature.
- a header that can sufficiently withstand the corrosiveness of the electrolytic solution used and the operating conditions such as pressure and temperature.
- iron, nickel, cobalt, PTFE, ETFE, PFA, polyvinyl chloride, polyethylene or the like may be adopted.
- the internal header type and external header type electrolytic cells 50 may have a gas-liquid separation box for separating the gas generated by electrolysis and the electrolytic solution.
- the mounting position of the gas-liquid separation box is not particularly limited, but may be mounted between the anode chamber 5a and the anode outlet header 10ao, or between the cathode chamber 5c and the cathode outlet header 10co.
- the surface of the gas-liquid separation box may be coated with a coating material that can sufficiently withstand the corrosiveness of the electrolytic solution and operating conditions such as pressure and temperature.
- an insulating material may be adopted for the purpose of increasing the electric resistance of the leakage current circuit inside the electrolytic cell.
- EPDM, PTFE, ETFE, PFA, polyvinyl chloride, polyethylene or the like may be adopted as the material of the coating material.
- the type of the electrode can be appropriately selected according to the type of electrolytic reaction. For example, in the case of alkaline water electrolysis, an electrode that generates oxygen gas at the anode and hydrogen gas at the cathode can be selected. In the case of salt electrolysis, an electrode that generates chlorine gas at the anode and hydrogen gas at the cathode can be selected.
- the electrolytic voltage of alkaline water electrolysis includes the overvoltage of the anode reaction (oxygen generation), the overvoltage of the cathode reaction (hydrogen generation), and the anode 2a and the cathode 2c. It is divided into the voltage according to the distance between the electrodes 2.
- the overvoltage means a voltage that needs to be excessively applied beyond the theoretical decomposition potential when a certain current is passed, and the value depends on the current value. When the same current is passed, power consumption can be reduced by using the electrode 2 having a low overvoltage.
- the requirements for the electrode 2 are high conductivity, high oxygen-evolving ability (or hydrogen-evolving ability), high wettability of the electrolytic solution on the surface of the electrode 2, and the like. Can be mentioned.
- the base material and catalyst layer of the electrode 2 may corrode, the catalyst layer may fall off, and the electrolyte may be charged. It is difficult for dissolution and adhesion of the inclusions to the diaphragm 4 to occur.
- the electrode base material is a porous body for the purpose of increasing the surface area and efficiently removing the gas generated by electrolysis from the electrode surface.
- the porous body include plain weave mesh, punching metal, expanded metal, metal foam and the like. Above all, a mesh structure is preferable from the viewpoint of ensuring a specific surface area as a carrier and achieving both defoaming property.
- the dimensions are not particularly limited, but the wire diameter is 0.05 mm in order to achieve both an increase in the amount of gas generated due to an increase in the surface area of electrolysis and an efficient removal of gas generated by electrolysis from the electrode surface.
- the pitch is 1.0 mm or more, the pitch is 20 mesh or more and 60 mesh or less, and the aperture ratio is 30% or more and 70% or less. More preferably, the wire diameter is 0.1 mm or more and 0.3 mm or less, the pitch is 30 mesh or more and 50 mesh or less, and the aperture ratio is 40% or more and 60% or less.
- the dimensions are not particularly limited, but in order to achieve both an increase in the amount of gas generated due to an increase in the surface area of electrolysis and efficient removal of gas generated by electrolysis from the electrode surface, and from the viewpoint of mechanical strength. Therefore, it is preferable that the hole diameter is 2 mm or more and 8 mm or less, the pitch is 2 mm or more and 10 mm or less, the aperture ratio is 20% or more and 80% or less, and the thickness is 0.5 mm or more and 2 mm or less.
- the dimensions are not particularly limited, but in order to achieve both an increase in the amount of gas generated due to an increase in the surface area of the electrolysis and an efficient removal of the gas generated by the electrolysis from the electrode surface, and from the viewpoint of mechanical strength. Therefore, the center-to-center distance (SW) in the short direction of the mesh is 2 mm or more and 5 mm or less, the center-to-center distance (LW) in the long direction of the mesh is 3 mm or more and 10 mm or less, the thickness is 0.5 mm or more and 2 mm or less, and the aperture ratio is It is preferably 20% or more and 80% or less.
- the SW is 3 mm or more and 4 mm or less
- the LW is 4 mm or more and 6 mm or less
- the thickness is 0.8 mm or more and 1.5 mm or less
- the aperture ratio is 40% or more and 60% or less.
- the dimensions are not particularly limited, but in order to achieve both an increase in the amount of gas generated due to an increase in the surface area of the electrolysis and an efficient removal of the gas generated by the electrolysis from the electrode surface, and in order to achieve mechanical strength.
- the porosity is preferably 80% or more and 95% or less
- the thickness is preferably 0.5 mm or more and 2.0 mm or less.
- the electrode may be the base material itself or may have a catalyst layer having high reaction activity on the surface of the base material, but those having a catalyst layer having high reaction activity on the surface of the base material are preferable.
- the material of the base material is preferably mild steel, stainless steel, nickel, or a nickel-based alloy, and more preferably a base material containing nickel, from the viewpoint of resistance to the usage environment.
- the catalyst layer of the anode 2a is preferably one having a high oxygen-evolving ability, and nickel, cobalt, iron, a platinum group element, or the like can be used. These can form a catalyst layer as a simple substance of a metal, a compound such as an oxide, a composite oxide or an alloy composed of a plurality of metal elements, or a mixture thereof in order to realize desired activity and durability.
- An organic substance such as a polymer may be contained in order to improve durability and adhesiveness to a base material.
- the catalyst layer of the cathode 2c is preferably one having a high hydrogen generating ability, and nickel, cobalt, iron, a platinum group element, or the like can be used. These can form a catalyst layer as a simple substance of a metal, a compound such as an oxide, a composite oxide or an alloy composed of a plurality of metal elements, or a mixture thereof in order to realize desired activity and durability. Organic substances such as polymer materials may be contained in order to improve durability and adhesiveness to a base material.
- a spraying method such as a plating method or a plasma spraying method, a thermal decomposition method in which heat is applied after applying a precursor layer solution on the substrate, and a catalytic substance mixed with a binder component.
- a method of immobilizing the material on the substrate and a vacuum film forming method such as a sputtering method can be mentioned.
- the catalyst layer of the anode preferably has a high oxygen generating ability, and nickel, cobalt, iron, or a platinum group element can be used, and a metal is used to achieve desired activity and durability.
- a catalyst layer formed by using a simple substance, a compound such as an oxide, a composite oxide or alloy containing a plurality of metal elements, or a mixture thereof is preferable.
- the catalyst layer of the cathode preferably has a high hydrogen generating ability, and nickel, cobalt, iron, a platinum group element or the like can be used.
- a conductive material is preferable from the viewpoint of realizing a uniform supply of electric power, and nickel plating is applied on nickel, nickel alloy, mild steel, and nickel alloy from the viewpoint of alkali resistance and heat resistance. Is preferable.
- the partition wall 1 and the outer frame 3 may be joined by welding or other methods to be integrated.
- a flange portion extending from the partition wall 1 in a direction perpendicular to the plane of the partition wall 1 ( An anode flange portion overhanging on the anode 2a side and a cathode flange portion overhanging on the cathode 2c side) may be provided, and the flange portion may be a part of the outer frame 3.
- the size of the partition wall 1 is not particularly limited, and may be appropriately designed according to the size of the electrode chamber 5.
- the thickness of the partition wall 1 may be 0.5 mm to 5 mm, and the vertical length and the horizontal length are not particularly limited.
- the shape of the partition wall 1 may be a plate-like shape having a predetermined thickness, but is not particularly limited.
- the partition wall 1 may be used so that the given direction D1 along the partition wall 1 is usually in the vertical direction, and specifically, as shown in FIGS. 5 and 6, the partition wall 1 may be used in a plan view.
- the shape is rectangular, it may be used so that the given direction D1 along the partition wall 1 is in the same direction as the direction of one of the two opposing sides.
- the shape of the outer frame 3 is not particularly limited as long as the partition wall 1 can be bordered, but the shape may be such that the inner surface along the direction perpendicular to the plane of the partition wall 1 is provided over the outer extension of the partition wall 1.
- the shape of the outer frame 3 is not particularly limited, and may be appropriately determined according to the plan-view shape of the partition wall 1.
- the dimensions of the outer frame 3 are not particularly limited, and may be designed according to the outer dimensions of the electrode chamber 5.
- the width of the outer frame 3 may be 10 mm to 40 mm, preferably 15 mm to 30 mm, and the extending length of the outer frame 3 is not particularly limited. In this case, the lengths of the anode flange portion and the cathode flange portion are not particularly limited, but may be 5 mm to 20 mm, preferably 7.5 mm to 15 mm, respectively.
- the material of the outer frame 3 a material having conductivity is preferable, and from the viewpoint of alkali resistance and heat resistance, nickel, nickel alloy, mild steel, and nickel alloy coated with nickel are preferable.
- the diaphragm 4 it is preferable to use an ion-permeable diaphragm 4 in order to separate the generated gas (for example, hydrogen gas and oxygen gas in the case of alkaline water electrolysis) while conducting ions.
- an ion exchange membrane having an ion exchange ability, a porous membrane capable of permeating an electrolytic solution, or the like can be used.
- the ion-permeable diaphragm 4 preferably has low gas permeability, high ion conductivity, low electron conductivity, and high strength.
- a polysulfone-based diaphragm is preferable.
- the porous membrane has a plurality of fine through holes and has a structure in which the electrolytic solution can permeate through the diaphragm 4. Since the electrolytic solution permeates into the porous membrane to develop ionic conduction, it is very important to control the porous structure such as pore size, porosity, and hydrophilicity. On the other hand, it is required that not only the electrolytic solution but also the generated gas do not pass through, that is, it has a gas blocking property. From this point of view, it is important to control the porous structure.
- the porous membrane has a plurality of fine through holes, and examples thereof include a polymer porous membrane, an inorganic porous membrane, a woven fabric, and a non-woven fabric.
- the porous membrane preferably contains a polymer material and hydrophilic inorganic particles, and the presence of the hydrophilic inorganic particles can impart hydrophilicity to the porous membrane.
- polysulfone examples include polysulfone, polyethersulfone, polyphenylsulfone, polyvinylidene fluoride, polycarbonate, tetrafluoroethylene / perfluoroalkyl vinyl ether copolymer, tetrafluoroethylene / ethylene copolymer, and polyvinylidene fluoride.
- polysulfone, polyethersulfone, polyphenylsulfone, polyphenylene sulfide, and polytetrafluoroethylene are preferable. These may be used alone or in combination of two or more. By using polysulfone, polyethersulfone, or polyphenylsulfone as the polymer material, resistance to high temperature and high concentration alkaline solutions is further improved. Polysulfone, polyethersulfone, and polyphenylsulfone may be crosslinked.
- the weight average molecular weight of the crosslinked polysulfone, polyethersulfone, and polyphenylsulfone is preferably 40,000 or more and 150,000 or less as the weight average molecular weight in terms of standard polystyrene.
- the method of the cross-linking treatment is not particularly limited, and examples thereof include cross-linking by irradiation with an electron beam or ⁇ -ray, thermal cross-linking with a cross-linking agent, and the like.
- the weight average molecular weight in terms of standard polystyrene can be measured by GPC. Commercially available products can also be used as the above-mentioned polymer materials.
- polysulfone examples include “Ultrason SPSU (registered trademark, the same shall apply hereinafter)" of BASF, and “Udel (registered trademark, the same shall apply hereinafter)” of Solvay Advanced Polymers.
- polyether sulfone examples include “Ultrason E PES (registered trademark, the same shall apply hereinafter)” of BASF, and “Radel A (registered trademark, the same shall apply hereinafter)” of Solvay Advanced Polymers.
- polyphenylsulfone examples include BASF's “Ultrason P PPSU (registered trademark, the same shall apply hereinafter)” and Solvay Advanced Polymers, Inc.
- the pore size of the porous membrane in order to obtain appropriate membrane properties such as separation ability and strength. Further, when used for alkaline water electrolysis, it is possible to control the pore size of the porous film from the viewpoint of preventing mixing of oxygen gas generated from the anode 2a and hydrogen gas generated from the cathode 2c and reducing voltage loss in electrolysis. preferable.
- the larger the average pore size of the porous membrane the larger the permeation amount of the porous membrane per unit area. In particular, in electrolysis, the ion permeability of the porous membrane becomes good, and the voltage loss tends to be easily reduced.
- the larger the average pore size of the porous membrane the smaller the contact surface area with alkaline water, so that the deterioration of the polymer tends to be suppressed.
- the smaller the average pore size of the porous membrane the higher the separation accuracy of the porous membrane, and the better the gas barrier property of the porous membrane in electrolysis.
- hydrophilic inorganic particles having a small particle size which will be described later, are supported on the porous membrane, they can be firmly held without being chipped. As a result, the high holding ability of the hydrophilic inorganic particles can be imparted, and the effect can be maintained for a long period of time.
- the average pore diameter is preferably 0.1 ⁇ m or more and 1.0 ⁇ m or less, and / or the maximum pore diameter is more than 0.1 ⁇ m and preferably in the range of 2.0 ⁇ m or less.
- the pore size of the porous membrane is controlled in the temperature range actually used. Therefore, for example, when used as an electrolytic diaphragm 4 in an environment of 90 ° C., it is preferable to satisfy the above-mentioned pore diameter range at 90 ° C.
- the porous membrane has an average pore diameter of 0.1 ⁇ m or more and 0.5 ⁇ m or less and / or a maximum pore diameter within a range in which better gas barrier property and high ion permeability can be exhibited as the alkaline water electrolysis diaphragm 4. Is more preferably 0.5 ⁇ m or more and 1.8 ⁇ m or less.
- the average pore diameter and the maximum pore diameter of the porous membrane can be measured by the following methods.
- the average pore size of the porous membrane means the average pore size measured by the following method using an integrity tester (“Sartorius Stedim Japan Co., Ltd.,“ Sartocheck Junior BP-Plus ”).
- an integrity tester (“Sartorius Stedim Japan Co., Ltd.,“ Sartocheck Junior BP-Plus ”).
- the porous membrane is cut into a predetermined size including the core material, and this is used as a sample. This sample is set in an arbitrary pressure-resistant container, and the inside of the container is filled with pure water.
- the pressure-resistant container is held in a constant temperature bath set to a predetermined temperature, and the measurement is started after the inside of the pressure-resistant container reaches the predetermined temperature.
- the average permeability hole diameter can be obtained from the following Hagen-Poiseuille equation using the gradient between the pressure and the permeability flow rate at which the pressure is between 10 kPa and 30 kPa.
- Average permeable hole diameter (m) ⁇ 32 ⁇ L ⁇ 0 / ( ⁇ P) ⁇ 0.5
- ⁇ is the viscosity of water (Pa ⁇ s)
- L is the thickness of the porous membrane (m)
- ⁇ 0 is the apparent flow velocity
- ⁇ 0 (m / s) flow rate (m 3 / s) / flow.
- ⁇ is the porosity and P is the pressure (Pa).
- the maximum pore size of the porous membrane can be measured by the following method using an integrity tester (“Sartorius Stedim Japan, Inc.,“ Sartocheck Junior BP-Plus ”).
- an integrity tester (“Sartorius Stedim Japan, Inc.,“ Sartocheck Junior BP-Plus ”).
- the porous membrane is cut into a predetermined size including the core material, and this is used as a sample.
- Wet this sample with pure water impregnate the pores of the porous membrane with pure water, and set this in a pressure-resistant container for measurement.
- the pressure-resistant container is held in a constant temperature bath set to a predetermined temperature, and the measurement is started after the inside of the pressure-resistant container reaches the predetermined temperature.
- the upper surface side of the sample is pressurized with nitrogen, and the nitrogen pressure when bubbles are continuously generated from the lower surface side of the sample is defined as the bubble point pressure.
- the maximum hole diameter can be obtained from the following bubble point equation, which is a modification of the Young-Laplace equation.
- Maximum hole diameter (m) 4 ⁇ cos ⁇ / P
- ⁇ is the surface tension of water (N / m)
- cos ⁇ is the contact angle between the surface of the porous membrane and water (rad)
- P bubble point pressure (Pa).
- the diaphragm 4 has a porosity of a porous membrane from the viewpoints of gas barrier property, maintenance of hydrophilicity, prevention of deterioration of ion permeability due to adhesion of bubbles, and long-term stable electrolytic performance (low voltage loss, etc.). It is preferable to control. From the viewpoint of achieving both gas breaking property and low voltage loss at a high level, the lower limit of the porosity of the porous membrane is preferably 30% or more, more preferably 35% or more, and more preferably 40% or more. Is even more preferable. The upper limit of the porosity is preferably 65% or less, more preferably 60% or less, and further preferably 55% or less. When the porosity of the porous membrane is not more than the above upper limit value, ions easily permeate through the membrane, and the voltage loss of the membrane can be suppressed.
- the porosity of the porous membrane refers to the open porosity determined by the Archimedes method, and can be determined by the following formula.
- Porosity P (%) ⁇ / (1 + ⁇ ) x 100
- ⁇ (W3-W1) / (W3-W2)
- W1 is the dry mass (g) of the porous membrane
- W2 is the underwater mass (g) of the porous membrane
- W3 is the satiety mass of the porous membrane (W3).
- a porous membrane washed with pure water is cut into three pieces having a size of 3 cm x 3 cm and used as a measurement sample.
- W2 and W3 of the sample are measured.
- the porous membrane is allowed to stand for 12 hours or more in a dryer set at 50 ° C. to dry, and W1 is measured.
- the porosity is obtained from the values of W1, W2, and W3.
- the porosity is obtained for three samples, and the arithmetic mean value thereof is defined as the porosity P.
- the thickness of the porous membrane is not particularly limited, but is preferably 100 ⁇ m or more and 700 ⁇ m or less, more preferably 100 ⁇ m or more and 600 ⁇ m or less, and further preferably 200 ⁇ m or more and 600 ⁇ m or less.
- the thickness of the porous membrane is at least the above lower limit value, more excellent gas blocking property can be obtained, and the strength of the porous membrane against impact is further improved.
- the gas barrier property becomes good.
- the lower limit of the thickness of the porous membrane is more preferably 300 ⁇ m or more, further preferably 350 ⁇ m or more, and further preferably 400 ⁇ m or more.
- the thickness of the porous membrane is not more than the above upper limit value, the resistance of the electrolytic solution contained in the pores during operation makes it difficult for the ion permeability to be hindered, and more excellent ion permeability can be maintained. .. Further, when it is not more than the above upper limit value, the voltage loss is unlikely to increase. In addition, the influence of variation in the thickness of the porous membrane is reduced. From this point of view, the upper limit of the thickness of the porous membrane is more preferably 600 ⁇ m or less, further preferably 550 ⁇ m or less, and further preferably 500 ⁇ m or less. In particular, when the polymer resin contains at least one selected from the group consisting of polysulfone, polyethersulfone and polyphenylsulfone, the effect is further improved.
- the porous membrane preferably contains hydrophilic inorganic particles in order to exhibit high ion permeability and high gas blocking property.
- the hydrophilic inorganic particles may be attached to the surface of the porous membrane, or may be partially embedded in the polymer material constituting the porous membrane. Further, when the hydrophilic inorganic particles are encapsulated in the voids of the porous membrane, it becomes difficult to separate from the porous membrane, and the performance of the porous membrane can be maintained for a long time.
- hydrophilic inorganic particles examples include oxides or hydroxides of zirconium, bismuth, and cerium; oxides of Group IV elements of the Periodic Table; nitrides of Group IV elements of the Periodic Table, and IV of the Periodic Table. At least one inorganic substance selected from the group consisting of carbides of group elements can be mentioned. Among these, from the viewpoint of chemical stability, oxides of zirconium, bismuth and cerium, oxides of Group IV elements of the Periodic Table are more preferable, oxides of zirconium, bismuth and cerium are more preferable, and zirconium oxide is preferable. Even more preferable.
- the particle surface of the hydrophilic inorganic particles is polar.
- the mode particle size of the hydrophilic inorganic particles is that of the secondary particles when the hydrophilic inorganic particles are present in the pores of the porous membrane, and is the particle size of the maximum value of the particle size distribution.
- the mode particle size can be measured by the following method.
- the polymer resin is dissolved and removed from the porous membrane using a solvent capable of dissolving the polymer resin.
- the remaining hydrophilic inorganic particles are repeatedly washed three or more times with the solvent in an amount 1000 times or more the weight of the hydrophilic inorganic particles.
- the mode particle size is measured from the volume distribution by the laser diffraction / scattering method.
- the mode particle size of the hydrophilic inorganic particles can be measured by, for example, a laser diffraction / scattering type particle size distribution measuring device (“LA-950” manufactured by HORIBA, Ltd.).
- the form of the hydrophilic inorganic particles is preferably a fine particle shape.
- the mode particle size of the hydrophilic inorganic particles used as a material for producing the porous film is preferably 0.1 ⁇ m or more and 10 ⁇ m or less.
- the mode particle size of the hydrophilic inorganic particles is 0.1 ⁇ m or more, for example, when the porous film is produced by the non-solvent-induced phase separation method, the viscosity of the polymer resin solution containing the hydrophilic inorganic particles becomes too high. However, since the occurrence of spots can be effectively suppressed during coating, it tends to be easy to produce a uniform porous film.
- the mode particle size of the hydrophilic inorganic particles is preferably 0.1 ⁇ m or more, more preferably 0.5 ⁇ m or more, further preferably 1.0 ⁇ m or more, and more preferably 2.0 ⁇ m or more. Even more preferable.
- the mode particle size of the hydrophilic inorganic particles is 10 ⁇ m or less, it is possible to prevent the bonding area between the hydrophilic inorganic particles and the porous film other than the inside of the pores from becoming too small with respect to the size of the hydrophilic inorganic particles. At the same time, it is possible to further suppress the removal of hydrophilic inorganic particles from the porous film. Further, it is possible to further prevent the porous membrane from being damaged by the hydrophilic inorganic particles. From this viewpoint, the mode particle size of the hydrophilic inorganic particles is preferably 10 ⁇ m or less, more preferably 8 ⁇ m or less, further preferably 6 ⁇ m or less, still more preferably 5 ⁇ m or less.
- the porous membrane When a porous membrane is used as the diaphragm 4, the porous membrane may be used together with a porous support. It is preferable that the porous film has a structure in which the porous support is embedded, and more preferably, it is a structure in which the porous film is laminated on both sides of the porous support. Further, the structure may be such that the porous membranes are symmetrically laminated on both sides of the porous support.
- porous support examples include a mesh, a porous film, a non-woven fabric, a woven fabric, a non-woven fabric, and a composite cloth including a woven fabric contained in the non-woven fabric. These may be used alone or in combination of two or more. More preferred embodiments of the porous support include, for example, a mesh substrate made of a monofilament of polyphenylene sulfide, or a composite fabric containing a nonwoven fabric and a woven fabric contained therein.
- the ion exchange membrane includes a cation exchange membrane that selectively permeates a cation and an anion exchange membrane that selectively permeates an anion, and any exchange membrane can be used.
- the material of the ion exchange membrane is not particularly limited, and known materials can be used.
- a fluorine-containing resin or a modified resin of a polystyrene / divinylbenzene copolymer can be preferably used.
- a fluorine-containing ion exchange membrane is preferable because it is excellent in heat resistance and chemical resistance.
- fluorine-containing ion exchange membrane examples include those having a function of selectively permeating ions generated during electrolysis and containing a fluorine-containing polymer having an ion exchange group.
- the fluorinated polymer having an ion exchange group as used herein means a fluorinated polymer having an ion exchange group or an ion exchange group precursor that can become an ion exchange group by hydrolysis.
- a polymer having a main chain of a fluorinated hydrocarbon, having a functional group that can be converted into an ion exchange group by hydrolysis or the like as a pendant side chain, and capable of melt processing can be mentioned.
- the molecular weight of the fluorine-containing copolymer is not particularly limited, but the precursor is measured by the melt flow index (MFI) value measured in accordance with ASTM: D1238 (measurement conditions: temperature 270 ° C., load 2160 g). It is preferably 0.05 to 50 (g / 10 minutes), and more preferably 0.1 to 30 (g / 10 minutes).
- MFI melt flow index
- Examples of the ion exchange group contained in the ion exchange film include a cation exchange group such as a sulfonic acid group, a carboxylic acid group and a phosphoric acid group, and an anion exchange group such as a quaternary ammonium group.
- the ion exchange membrane can impart excellent ion exchange ability and hydrophilicity by adjusting the equivalent mass EW of the ion exchange group. In addition, it can be controlled to have a large number of smaller clusters (microparts in which the ion exchange group coordinates and / or adsorbs water molecules), and tends to improve alkali resistance and ion selective permeability.
- This equivalent mass EW can be measured by substituting the ion exchange membrane with a salt and back-titrating the solution with an alkaline or acid solution.
- the equivalent mass EW can be adjusted by the copolymerization ratio of the monomer as a raw material, the selection of the monomer type, and the like.
- the equivalent mass EW of the ion exchange membrane is preferably 300 or more from the viewpoint of hydrophilicity and water resistance of the membrane, and preferably 1300 or less from the viewpoint of hydrophilicity and ion exchange ability.
- the thickness of the ion exchange membrane is not particularly limited, but the range of 5 ⁇ m to 300 ⁇ m is preferable from the viewpoint of ion permeability and strength.
- Surface treatment may be applied for the purpose of improving the hydrophilicity of the surface of the ion exchange membrane.
- Specific examples thereof include a method of coating hydrophilic inorganic particles such as zirconium oxide and a method of imparting fine irregularities on the surface.
- the ion exchange membrane is preferably used together with a reinforcing material from the viewpoint of membrane strength.
- the reinforcing material is not particularly limited, and examples thereof include general non-woven fabrics, woven fabrics, and porous membranes made of various materials.
- the porous membrane in this case is not particularly limited, but a stretched and porous PTFE membrane is preferable.
- the gasket 7 is sandwiched between the outer frames 3 bordering the partition wall 1 together with the diaphragm 4.
- the gasket is used to seal between the element 60 and the diaphragm 4 and between the elements 60 against the electrolytic solution and the generated gas, and the electrolytic solution and the generated gas leak out of the electrolytic cell and the gas between the electrode chambers. Mixing can be prevented.
- the general structure of the gasket 7 is a square shape or an annular shape in which the electrode surface is hollowed out according to the surface of the element in contact with the frame body.
- the diaphragm 4 can be stacked between the elements by sandwiching the diaphragm 4 with two such gaskets.
- the gasket 7 is provided with a slit portion capable of accommodating the diaphragm 4 so as to be able to hold the diaphragm 4, and is provided with an opening which allows the accommodated diaphragm 4 to be exposed on both surfaces of the gasket 7. It is also preferable.
- the gasket 7 has a structure in which the edge portion of the diaphragm 4 is accommodated in the slit portion and the end surface of the edge portion of the diaphragm 4 is covered. Therefore, it is possible to more reliably prevent the electrolytic solution and gas from leaking from the end surface of the diaphragm 4.
- the material of the gasket 7 is not particularly limited, and a known rubber material, resin material, or the like having insulating properties can be selected.
- the rubber material and resin material include natural rubber (NR), styrene-butadiene rubber (SBR), chloroprene rubber (CR), butadiene rubber (BR), acrylonitrile-butadiene rubber (NBR), and silicone rubber (SR). ), Ethylene-propylene rubber (EPT), ethylene-propylene-diene rubber (EPDM), fluororubber (FR), isobutylene-isoprene rubber (IIR), urethane rubber (UR), chlorosulfonated polyethylene rubber (CSM) and other rubbers.
- NR natural rubber
- SBR styrene-butadiene rubber
- CR chloroprene rubber
- BR butadiene rubber
- NBR acrylonitrile-butadiene rubber
- silicone rubber silicone rubber
- EPT Ethylene-prop
- PTFE polytetrafluoroethylene
- PFA tetrafluoroethylene / perfluoroalkyl vinyl ether copolymer
- ETFE tetrafluoroethylene / ethylene copolymer
- ECTFE chlorotrifluoroethylene / ethylene copolymer
- Fluororesin materials and resin materials such as polyphenylene sulfide (PPS), polyethylene, polyimide, and polyacetal can be used.
- PPS polyphenylene sulfide
- EPDM ethylene-propylene-diene rubber
- FR fluororubber
- a reinforcing material may be embedded in the gasket 7.
- metal materials, resin materials, carbon materials and the like can be used as such reinforcing materials, and specifically, metals such as nickel and stainless steel, resins such as nylon, polypropylene, PVDF, PTFE and PPS, carbon particles and carbon. Examples include carbon materials such as fibers.
- the size of the gasket 7 is not particularly limited and may be designed according to the dimensions of the electrode chamber 5 and the film, but the width is preferably 10 mm to 40 mm. In this case, when the gasket 7 includes a slit portion, the size of the slit portion should be such that the inner dimension of the slit is 0.5 mm to 5 mm larger in the vertical and horizontal directions than the size of the membrane.
- the thickness of the gasket 7 is not particularly limited, and is designed according to the material, elastic modulus, and cell area of the gasket 7.
- the preferred thickness range is preferably 1.0 mm to 10 mm, more preferably 3.0 mm to 10 mm.
- the opening width of the slit portion may be 0.5 to 1.0 times the thickness of the film.
- the elastic modulus of the gasket 7 is not particularly limited, and is designed according to the material of the electrode 2 and the cell area.
- the tensile stress at the time of 100% deformation is more preferably in the range of 0.20 MPa to 20 MPa, and more preferably in the range of 1.0 MPa to 10 MPa from the viewpoint of sealing characteristics and cell strength at the time of stacking. ..
- the tensile stress can be measured according to JIS K6251. For example, Autograph AG manufactured by Shimadzu Corporation may be used.
- the thickness of the gasket 7 is 3.0 mm to 10 mm, and the tensile stress at the time of 100% deformation is 1.0 MPa to 10 MPa from the viewpoint of suppressing the increase in cell voltage due to electrode deflection, and the sealing characteristics. It is preferable from the viewpoint of cell strength at the time of stacking.
- the electrolytic cell 50 has a liquid level gauge capable of measuring the liquid level in each of the electrode chambers 5a and 5c of the electrolytic cell 50.
- the liquid level gauge monitors the liquid level in each electrode chamber 5a and 5c (monitors the height of the liquid level in the electrode chambers 5a and 5c), and the surface of the diaphragm 4 in each electrode chamber 5a and 5c. It is possible to grasp whether the electrode is immersed in the electrolytic solution or is not immersed in the electrolytic solution.
- the liquid level gauge is not particularly limited, and for example, a direct-view type, a contact type, or a differential pressure type liquid level gauge can be used.
- the pressure gauge 78 may be installed inside the electrolytic cell or outside the electrolytic cell. When a plurality of electrolytic cells are provided, the pressure may be measured collectively for the gas discharged from one electrode of all the electrolytic cells.
- the liquid feed pump 71 is not particularly limited and may be appropriately defined.
- the liquid feed pump 71 can circulate the electrolytic solution flowing through the electrolytic cell 50 and the pipe 81.
- a cathode side liquid feed pump for feeding liquid to the cathode chamber 5c and an anode side liquid feed pump for feeding liquid to the anode chamber 5a can be provided, and each can be operated separately.
- the gas-liquid separation tank 72 is preferably a tank that separates the electrolytic solution and the gas generated in the electrolytic cell, and is an anode-side gas-liquid separation tank 72a that separates the gas generated at the anode of the electrolytic cell and the electrolytic cell. It is preferable that the gas-liquid separation tank 72c on the cathode side separates the gas generated at the cathode of the electrolytic cell and the electrolytic cell. For example, in the case of alkaline water electrolysis, oxygen is generated at the anode and hydrogen is generated at the cathode.
- the anode-side gas-liquid separation tank 72a is an oxygen separation tank
- the cathode-side gas-liquid separation tank 72c is a hydrogen separation tank.
- the gas-liquid separation tank 72 for the anode chamber 5a separates the oxygen gas and the electrolytic solution generated in the anode chamber 5a
- the gas-liquid separation tank 72 for the cathode chamber 5c separates the hydrogen gas and the electrolytic solution generated in the cathode chamber 5c.
- the electrolytic solution and the generated gas discharged from the electrolytic cell 65 in a mixed state are allowed to flow into the gas-liquid separation tank 72. If the gas-liquid separation is not properly performed, oxygen gas and hydrogen gas are mixed when the electrolytic solutions of the cathode chamber 5c and the anode chamber 5a are mixed, and the purity of the gas is lowered. In the worst case, there is a risk of forming a roar.
- the gas and electrolytic solution that flowed into the gas-liquid separation tank 72 are separated into the gas phase in the upper layer of the tank and the electrolytic solution in the liquid phase in the lower layer of the tank.
- the degree of gas-liquid separation is determined by the line bundle of the electrolytic solution in the gas-liquid separation tank 72, the floating speed of the generated gas bubbles, and the residence time in the gas-liquid separation tank 72.
- the electrolytic solution flows out from the outlet below the tank and flows into the electrolytic cell 65 again to form a circulation path. Since both oxygen and hydrogen gas discharged from the discharge port above the tank contain alkaline mist, excess mist such as a mist separator and a cooler is liquefied and separated into gas and liquid downstream of the discharge port. It is preferable to attach a device that can be returned to the tank 72.
- the gas-liquid separation tank 72 may be equipped with a liquid level gauge in order to grasp the liquid level height of the electrolytic solution stored inside.
- the gas-liquid separation tank 72 is provided with a pressure release valve. As a result, even if the pressure rises due to the gas generated by electrolysis, the pressure can be safely lowered when the design pressure is exceeded.
- the inflow port to the gas-liquid separation tank 72 is preferably located on the upper surface of the electrolytic solution surface in order to improve the gas-liquid separation property, but is not limited thereto.
- the electrolytic liquid level in the gas-liquid separation tank 72 is higher than the upper surface of the electrolytic cell.
- a shutoff valve to be provided between the electrolytic cell 65 and the gas-liquid separation tank 72.
- Alkaline resistant metal such as nickel is used as the material of the gas-liquid separation tank 72.
- the electrolytic solution contact surface inside the tank may be coated with a fluororesin or the like.
- the material of the separation tank 72 is not limited.
- the capacity of the gas-liquid separation tank 72 is preferably small in consideration of the installation volume, but if the volume is too small, the pressure difference between the cathode 2c and the anode 2a becomes large, or the electrolytic current value fluctuates. Since the liquid level in the tank fluctuates, it is necessary to take this fluctuation into consideration. Similarly, when the height of the tank is low, it is easily affected by the above fluctuations, so it is preferable to increase the height of the tank.
- the water replenisher 73 is not particularly limited and may be appropriately defined.
- As the water general clean water may be used, but in consideration of long-term operation, it is preferable to use ion-exchanged water, RO water, ultrapure water, or the like.
- the electrolyzer 70 may have a storage tank for storing the electrolytic solution. Further, it is preferable that the storage tank is located above the electrolytic cell 50 of the electrolytic cell 70 in the vertical direction. By connecting the storage tank to the electrolytic cell 50 by a pipe or the like, the electrolytic solution in the storage tank can be injected into the electrolytic cell by utilizing gravity. Further, the flow rate can be appropriately adjusted by providing a valve or the like in the pipe or the like.
- the pipe 81 is not particularly limited and may be appropriately defined.
- the pipe 81 is a pipe for flowing the electrolytic solution to the outside of the electrolytic cell 50.
- the electrolytic cell 50 and the gas-liquid separation tank 72, the gas-liquid separation tank 72 and the liquid feed pump 71, and the liquid feed pump 71 and the electrolytic cell 50 can be connected.
- the gas separated by the gas-liquid separation tank 72, the pressure gauge 78, the pressure control valve 80, and the densitometer are preferably connected by a gas pipe.
- the power supply is preferably a DC power supply.
- the supply power source may be a power source using electric power obtained by power generation from an energy source whose output fluctuates, such as renewable energy (variable power source), or a power source having a substantially constant output (constant power source). It may be a combination of these. Above all, from the viewpoint of suppressing the generation of greenhouse gases, it is preferable to use a variable power source, and at least one renewable energy selected from the group consisting of wind power, solar power, hydraulic power, tidal power, wave power, sea current, and geothermal power. A power source derived from an output is more preferable, and a power source derived from a solar output or a power source derived from a wind power output is further preferable.
- the constant power source examples include a power source of power supplied through the grid, a storage battery power source, and the like.
- the power source supplied through the grid may be a power source derived from a stable power source such as thermal power or nuclear power, or a combination of a variable power source derived from a renewable energy output or the like and a power source derived from a stable power source. May be good.
- the electric power supplied from the above power source may be converted into direct current by a rectifier before being supplied to the electrolytic cell.
- One rectifier may be provided immediately before the electrolytic cell, or may be provided between each power source and the electrolytic cell.
- the electrolytic device 70 further includes a detector for detecting the stop of the power supply and a controller for automatically stopping the liquid feed pump.
- Examples of the above electrolysis include water electrolysis such as alkaline water electrolysis and salt electrolysis.
- alkaline water electrolysis in which the amount of gas generated from the electrodes is large and the tightening load of the electrolytic cell fluctuates greatly, is preferable.
- the electrolyzer 70 it is preferable that at least a part of the cathode 2c is above the uncoated upper end 4t of the diaphragm 4 in the vertical direction D1.
- the waterline L (position 31 of the liquid surface) of the electrolytic solution in the anode chamber 5a and / or the cathode chamber 5c is more vertical than the uncoated upper end 4t of the diaphragm 4.
- At least a portion of the cathode 2c can be exposed to a hydrogen gas layer that may be present in the cathode chamber 5c while being located upward in the direction. As a result, it is possible to suppress the diffusion and mixing of the gas between the electrode chambers 5a and 5c via the diaphragm when the electrolysis is stopped, and further suppress the deterioration of the cathode 2c.
- the respective electrodes The gas in the chambers 5a and 5c may slightly permeate the diaphragm 4 and diffuse into the respective electrode chambers 5a and 5c.
- a part of the cathode 2c is converted to hydrogen gas in the stopping step.
- a reverse current is generated in the cathode 2c during the stop step due to the electric charge accumulated in the cathode (and the anode 2a) during the energization step, and the reverse
- the cathode itself was sometimes oxidized (during the energization process, a reduction reaction occurs in the cathode chamber). Then, there is a concern that the cathode 2c deteriorates due to the repeated energization step and stop step.
- non-covered upper end of the diaphragm is the upper end of the diaphragm 4 in the vertical direction D1, or the portion of the diaphragm itself on the upper end side of the vertical direction D1 is, for example, FIG. 7 (a).
- FIG. 8 when a part of the surface of the diaphragm 4 is covered with a gasket or the like used when fixing the diaphragm 4 between the outer frames 3 of the electrolytic tank 50, or as shown in FIG.
- the gasket 7 When a part of the surface of the diaphragm 4 is covered with the covering material 41 as described later, the “non-covered upper end of the diaphragm” is covered with the gasket 7 of the diaphragm 4, the covering material 41, or the like. Refers to the upper end of the vertical direction D1 for the non-existing portion.
- FIGS. 7A and 7B schematically representing the cathode chamber 5c
- the cathode 2c the cathode main body 2c1 and the cathode main body 2c1
- the cathode auxiliary portion 2c2 connected by the lead wire portion 2c3, and at least a part of the cathode auxiliary portion 2c2 above the vertical direction D1 is as shown in FIG. 7 (a).
- the cathode 2c having the cathode auxiliary portion 2c2 By having the cathode 2c having the cathode auxiliary portion 2c2 in this way, the waterline L of the electrolytic solution is positioned as shown in the figure in the stop step, so that the cathode auxiliary portion 2c2 oxidizes the hydrogen gas even if a reverse current is generated. By doing so, it is possible to prevent the deterioration of the cathode 2c and prevent the mixing of oxygen into the hydrogen present in the cathode chamber 5c, which may occur due to the surface of the diaphragm 4 being exposed to the gas in the stopping step.
- the cathode 2c does not have the cathode auxiliary portion 2c2 separated from the cathode main body 2c1, but the cathode 2c is composed of only the cathode main body 2c1 and the upper end of the vertical direction D1 of the cathode main body 2c1 is formed.
- the cathode auxiliary portion 2c2 of FIG. 7A extended to the upper end position in the vertical direction D1 can also be used.
- the cathode 2c has the cathode auxiliary portion 2c2 as shown in FIG. 7A, it is possible to make it easier to replace the cathode 2c at the time of maintenance as compared with the one not having the cathode 2c.
- the size of the cathode 2c as a whole can be reduced by using the cathode auxiliary portion 2c2, or for example, the cathode auxiliary portion 2c2 makes the electrolytic performance during the energization process lower than that of the cathode main body portion 2c2 (for example). Since the amount of catalyst can be reduced, etc.), the cost of the cathode 2c can be reduced.
- the cathode main body 2c1 is an electrode for electrolyzing the electrolytic solution in the energization step like the cathode 2c when the cathode auxiliary portion 2c2 is not provided, and the cathode 2c when the cathode auxiliary portion 2c2 is not provided. It can have the same structure and material as. Further, the cathode auxiliary portion 2c2 can be formed of a material that can be used for the cathode main body portion 2c1, or can be made of the same material as the cathode main body portion 2c1, but comes into contact with hydrogen when a reverse current is generated. It is not particularly limited as long as it can be oxidized.
- the length in the vertical direction D1 and the length in the direction orthogonal to the vertical direction D1 are the cathodes. It is smaller than the length of the main body 2c1 in the horizontal direction and the length in the direction orthogonal to the vertical direction D1.
- the specific dimensions are not particularly limited as long as the cathode auxiliary portion 2c2 is smaller than the size that can be accommodated in the cathode chamber 5c together with the cathode main body portion 2c1, and the length of the cathode auxiliary portion 2c2 in the vertical direction D1 is preferably 90 mm or less.
- the lead wire portion 2c3 connected to the cathode main body portion 2c1 and the cathode auxiliary portion 2c2 can be formed of a material that can be used as the base material of the cathode 2c, or can be made of the same material as the cathode main body portion 2c1.
- the covering material 41 that covers the surface of the diaphragm 4 as used in the example of FIG. 8 is not used, but the covering material 41 can also be used.
- the electrolytic device 70 in which at least a part of the cathode 2c is present above the uncoated upper end 4t of the diaphragm 4 it is preferable to use the electrolytic device 70 shown in FIG. 8 instead of the example shown in FIG.
- the surface of the diaphragm 4 is covered with the covering material 41 so that the lower end in the vertical direction of the covering material 41 is the uncoated upper end 4t of the diaphragm 4. More specifically, a part of the surface of the diaphragm 4 is covered with the covering material 41 together with the gasket 7, so that at least a part of the cathode 2c is larger than the uncoated upper end 4t of the diaphragm 4.
- the covering material 41 can cover the surface of the diaphragm 4, and when the portion of the diaphragm 4 covered with the covering material 41 is present in the gas, the partition is divided by the diaphragm 4.
- the covering material 41 is provided on both surfaces of the diaphragm 4 in FIG. 8, when the portion of the diaphragm 4 covered with the covering material 41 is present in the gas, the covering material 41 is partitioned by the diaphragm 4.
- the gas from each of the electrode chambers 5a and 5c may be provided on only one surface of the diaphragm 4. In this way, when the positions of the upper end of the uncoated surface in the vertical direction are different on the surfaces of the diaphragm 4 on one side and the other side, and the range covered by the surfaces on the one side and the other side is different, the vertical direction is used.
- the uncovered upper end of the lower surface is referred to as the "uncovered upper end of the diaphragm".
- the covering material 41 is provided on the surface of the diaphragm 4, the surface is covered with the covering material 41 from the upper end of the diaphragm 4 (if the surface on the upper end side of the diaphragm 4 is covered with a gasket or the like, the gasket). It is preferable that the lower end of the covering material 41 in the vertical direction D1 is located below the upper end of the vertical direction D1 of the cathode 2c so as to be below the position of the upper end in the vertical direction D1.
- the lower end of the covering material 41 in the vertical direction D1 is below the position of the upper end of the vertical direction D1 of the cathode 2c and vertically below the position of the upper end of the vertical direction D1 of the cathode 2c. It is above the vertical direction D1 from the position separated 20 mm downward in the direction D1, and more preferably than the position where the lower end thereof is separated 10 mm below the vertical direction D1 from the position of the upper end of the vertical direction D1 of the cathode 2c. It is above D1 in the vertical direction.
- Examples of the method of using the present embodiment include the above-mentioned method of using the electrolytic system of the present embodiment.
- the liquid level height control means is operated when the energization of the electrolytic cell is stopped, and the liquid level height of the electrolytic solution in the electrolytic cell in the electrolytic cell is adjusted and used.
- the current value supplied to the electrolytic cell may be 0A, and the operation at a low current value in which the liquid level height of the electrolytic solution in the electrolytic cell decreases in the vertical downward direction is included. May be good.
- the liquid feeding pump 71 that circulates the electrolytic solution when the electrolytic system is operating may also be in a stopped state.
- the liquid level height is increased in response to the above-mentioned trigger or the like in a state where the electric power (for example, current) supplied to the electrolytic cell is stopped and the liquid feed pump for circulating the electrolytic solution is also stopped. It is preferable to adjust the liquid level by the control means 30.
- the above electrolytic system is used by circulating the electrolytic solution when energized.
- the electrolytic solution mixed with the gas generated at the electrodes is discharged from the discharge port of the electrolytic cell, and is separated into the electrolytic solution and the gas in the gas-liquid separation tank.
- the electrolytic solution from which the gas has been separated is supplied again to the electrolytic cell through the liquid feed pump 71 or the like.
- the electrolytic solutions discharged from the anode-side gas-liquid separation tank 72a and the cathode-side gas-liquid separation tank 72c are mixed and sent to the multipolar electrolytic cell 50. It is preferable (Fig. 1).
- the electrolysis system can be used, for example, for alkaline water electrolysis and salt electrolysis.
- alkaline water electrolysis an alkaline aqueous solution in which an alkaline salt is dissolved may be used as the electrolytic solution, a NaOH aqueous solution, a KOH aqueous solution, or the like is used to produce hydrogen gas generated at the cathode and / or generated at the anode. It may be used in the production of oxygen gas.
- the concentration of the alkaline salt is preferably 20% by mass to 50% by mass, more preferably 25% by mass to 40% by mass.
- salt water and NaOH may be used as the electrolytic solution and used for the production of hydrogen gas generated at the cathode and / or the production of chlorine gas generated at the anode.
- the temperature of the electrolytic solution in the electrolytic cell 50 is preferably 80 ° C to 130 ° C, more preferably 85 ° C to 125 ° C, and particularly preferably 90 ° C to 115 ° C. .. Within the above temperature range, it is possible to effectively suppress deterioration of the members of the electrolysis system 70 such as the gasket 7 and the diaphragm 4 due to heat while maintaining high electrolysis efficiency.
- the operation method of the other electrolytic apparatus of this embodiment can be carried out by using the electrolytic apparatus 70 described above. Specifically, it is a method of operating an electrolytic apparatus 70 using an electrolytic apparatus 70 having an anode chamber 5a having an anode 2a and a cathode chamber 5c having a cathode 2c, which are mutually partitioned by a diaphragm 4. It has an energization step in which electrolysis of the electrolytic solution in the anode chamber 5a and the cathode chamber 5c is performed, and a stop step in which the electrolysis of the electrolytic solution in the anode chamber 5a and the cathode chamber 5c is stopped.
- Examples thereof include a method in which the liquid level L of the electrolytic solution in the anode chamber a and / or the cathode chamber 5c is located vertically above the uncoated upper end 4t of the diaphragm 4. According to the operation method, it is possible to further suppress the diffusion / mixing of gas between the electrode chambers 5a and 5c via the diaphragm 4 when the electrolysis is stopped.
- the energization step is a step in which the electrolytic solution in the anode chamber 5a and the cathode chamber 5c is electrolyzed.
- the electrolytic solution is sent to the anode chamber 5a and the cathode chamber 5c of the electrolytic cell 50 by using the liquid feeding pump 71, and is positively energized from the rectifier 74.
- the electrolytic solution in the anode chamber 5a and the cathode chamber 5c is electrolyzed.
- the electrolytic solution containing oxygen and the electrolytic solution containing hydrogen generated by electrolysis are sent from the anode chamber 5a and the cathode chamber 5c to the gas-liquid separation tank 72, respectively, and separated into gas and liquid. Further, the electrolytic solution separated by gas and liquid in the gas-liquid separation tank 72 returns to the liquid feeding pump 71 while being replenished with water by the water replenisher 73. As described above, in the energization step, the electrolytic solution is electrolyzed while circulating, so that the electrolysis can be efficiently performed.
- positive energization refers to energizing electricity in a direction in which oxygen can be obtained from the anode 2a and hydrogen can be obtained from the cathode 2c in the case of alkaline water electrolysis.
- the electrolytic solution used in the above method may be an alkaline aqueous solution in which an alkaline salt is dissolved, and examples thereof include a NaOH aqueous solution and a KOH aqueous solution.
- concentration of the alkaline salt is preferably 20% by mass to 50% by mass, more preferably 25% by mass to 40% by mass. Of these, a 25% by mass to 40% by mass KOH aqueous solution is particularly preferable from the viewpoints of ionic conductivity, kinematic viscosity, and freezing by cooling.
- the temperature of the electrolytic solution in the electrolytic cell 65 is preferably 80 ° C to 130 ° C. Within the above temperature range, it is possible to effectively suppress deterioration of the members of the electrolytic apparatus 70 such as the gasket 7 and the diaphragm 4 due to heat while maintaining high electrolytic efficiency.
- the temperature of the electrolytic solution is more preferably 85 ° C to 125 ° C, and particularly preferably 90 ° C to 115 ° C.
- the current density applied to the electrolytic cell 65 is preferably 4kA / m 2 ⁇ 20kA / m 2, further preferably 6kA / m 2 ⁇ 15kA / m 2.
- the pressure (gauge pressure) in the electrolytic cell 65 is preferably 3 kPa to 1000 kPa, more preferably 3 kPa to 300 kPa, and further preferably 3 kPa to 100 kPa.
- the stop step is a step in which the electrolysis of the electrolytic solution in the anode chamber 5a and the cathode chamber 5c is stopped.
- oxygen is generated by the electrolysis of the electrolytic solution in the anode chamber 5a
- hydrogen is generated by the electrolysis of the electrolytic solution in the cathode chamber 5c.
- positive energization may be performed as long as the energization amount is 1% or less of the maximum positive energization amount (kA / m 2) allowed to flow through the electrolytic device 70.
- the maximum positive energization amount means the maximum positive energization amount allowed as an operating condition in the electrolytic apparatus 70 used. Further, in the stop step, the liquid feed pump 71 may be stopped or may be in a moved state, but it is preferable to stop the liquid feed pump 71.
- the stop step as shown in FIGS. It is preferably located above 4t in the vertical direction. In this case, it is possible to further suppress the diffusion and mixing of the gas between the electrode chambers 5a and 5c via the diaphragm 4 when the electrolysis is stopped.
- the gas generated during the operation remains as a gas layer together with the electrolytic solution during the electrolytic operation in the electrode chamber of the electrolytic cell. As a result, a part (both sides) of the diaphragm dividing the electrode chamber into the anode chamber and the cathode chamber may be exposed to the gas layer existing in each electrode chamber.
- the gas in the respective electrode chambers 5 may slightly permeate the diaphragm 4 and diffuse into the respective electrode chambers 5.
- at least one surface of the diaphragm 4 is in a state of being immersed in the liquid. Therefore, it is possible to suppress the diffusion and mixing of gas between the electrode chambers 5a and 5c through the diaphragm 4, and therefore, for example, the hydrogen concentration in oxygen in the anode chamber 5a and the hydrogen in the cathode chamber 5c. It is possible to avoid a local increase in oxygen concentration.
- the above-mentioned "upper end of uncoated septum” (upper end of the septum exposed in the electrode chamber) is the upper end of the vertical direction D1 of the septum 4 or the vertical direction D1 of the septum 4 itself.
- the upper end side portion is partially covered with a gasket or the like used for fixing the diaphragm 4 between the outer frames 3 of the electrolytic cell.
- the “non-covered upper end of the diaphragm” is the gasket 7 of the diaphragm 4.
- liquid level L of the electrolytic solution in the anode chamber 5a and the liquid level L (liquid level 31) of the electrolytic solution in the cathode chamber 5c may be the same or different from each other in the vertical direction.
- the method of locating the liquid level L of the electrolytic solution in the anode chamber 5a and / or the cathode chamber 5c vertically above the uncoated upper end 4t of the diaphragm 4 is not particularly limited, but is not particularly limited, for example.
- a method of injecting an electrolytic solution into the anode chamber 5a and / or the cathode chamber 5c using a liquid feed pump 71 can be mentioned.
- the liquid feed pump 71 is operated continuously or intermittently, and the liquid level L of the anode chamber 5a and / or the cathode chamber 5c is moved vertically upward from the uncoated upper end 4t of the diaphragm 4.
- the electrolytic solution may be continuously circulated by continuously operating the liquid feed pump 71. Further, the liquid feed pump 71 may be continuously or intermittently operated after the transition from the energization process to the stop process, or continuously or intermittently after the transition to the stop process for a certain period of time. Can be done.
- the electrolytic device 70 has a cathode side liquid feed pump for sending liquid to the cathode chamber 5c and an anode side liquid feed pump for sending liquid to the anode chamber 5a as the liquid feed pump 71, they are separately used. It can be operated. As a result, it is possible to more efficiently suppress an increase in the hydrogen concentration in oxygen and the oxygen concentration in hydrogen in the cathode chamber 5c.
- the electrolytic device 70 has a storage tank for storing the electrolytic solution and the storage tank. Is located vertically above the electrolytic cell 50 of the electrolytic cell 70, the electrolytic solution in the storage tank is injected into the anode chamber 5a and / or the cathode chamber 5c by using gravity in the stopping step. Can also be done by. As a result, at least one surface of the diaphragm 4 can be immersed by the electrolytic solution in the electrode chambers 5a and 5c without using power. In this case, gravity can be used to fill the anode chamber 5a and / or the cathode chamber 5c with the electrolytic solution in the tank.
- the liquid feeding pump 71 can be stopped or operated to the extent that the liquid amount does not change after the injection.
- the inlets and pipes for example, the electrolytic solution inlet 5i and the anode inlet header (anode inlet) below the electrode chambers 5a and 5c in the vertical direction are stopped.
- the electrolytic cell 50 is provided with a liquid level gauge capable of measuring the liquid level L in the anode chamber 5a and the cathode chamber 5c of the electrolytic cell 50, and the anode chamber 5a and the anode chamber 5a are provided by the liquid level gauge. It is preferable to monitor the liquid level L in the cathode chamber 5c.
- each liquid level L is monitored by a liquid level gauge in the stop step, and the liquid level L in the anode chamber 5a and the cathode chamber 5c is higher than the uncoated upper end 4t of the diaphragm 4.
- the electrolytic solution is injected into the anode chamber 5a and / or the cathode chamber 5c by the liquid feed pump 71, and the liquid level L of the anode chamber 5a and / or the cathode chamber 5c is not covered with the diaphragm 4. It is preferable to position it above the upper end 4t in the vertical direction.
- each liquid level L is monitored by a liquid level gauge, and when the liquid level L in the anode chamber 5a and the cathode chamber 5c approaches the uncoated upper end 4t of the diaphragm 4, the liquid feed pump It is also preferable to inject the electrolytic solution into the anode chamber 5a and / or the cathode chamber 5c by 71 to push up the liquid level L.
- the electrolytic solution in the electrode chambers 5a and 5c decreases during the stopping step, at least one of the surfaces of the diaphragm 4 can be continuously immersed.
- the electrolytic apparatus 70 in which at least a part of the cathode 2c is present above the uncoated upper end 4t of the diaphragm 4.
- the stopping step when the liquid level L of the electrolytic solution in the cathode chamber 5c is located vertically above the uncoated upper end 4t of the diaphragm 4, at least a part of the cathode 2c is in the cathode chamber 5c. It can be exposed to a hydrogen gas layer that can be present in the.
- the cathode 2c is exposed to hydrogen gas in a part thereof, so that even if a reverse current of the cathode 2c is generated, the hydrogen in contact with the cathode 2c is oxidized.
- the oxidation of the cathode 2c itself can be reduced, and the deterioration of the cathode 2c can be suppressed.
- hydrogen gas is supplied to the cathode chamber 5c from the outside of the cathode chamber 5c in the stopping step, and hydrogen is supplied to the cathode chamber 5c. It is preferable to form a gas layer.
- the electrolytic cell 50 is provided with a liquid level gauge, the liquid level L of the electrolytic solution in the anode chamber 5a and / or the cathode chamber 5c is vertically above the uncoated upper end 4t of the diaphragm 4 by the liquid level gauge. It is preferable to monitor whether the cathode 2c is located below the vertical position of the cathode 2c while being located at.
- the cathode chamber 5c As a specific method of supplying hydrogen gas to the cathode chamber 5c from the outside of the cathode chamber 5c to form a hydrogen gas layer in the cathode chamber 5c, there is a method of forming a hydrogen gas layer in the cathode chamber 5c at the upper end of the vertical direction D1 of the cathode electrolyte outlet 5co of the cathode chamber 5c.
- the electrolyzer is positioned below the vertical direction D1 from the position of the upper end of the vertical direction D1 on the inner surface of the outer frame 3 of the cathode chamber 5c, and below the vertical direction D1 from the upper end of the vertical direction D1 of the cathode 2c.
- the hydrogen gas layer (hydrogen pool) can be continuously formed above the vertical direction D1 in the cathode chamber 5c.
- the distribution direction is the direction in which the electrolytic solution flows in the electrolytic device 70 in the energization step of the electrolytic device 70 or the like.
- the hydrogen gas supplied from the outside of the cathode chamber 5c can be injected from the storage tank by connecting the storage tank for storing hydrogen after the hydrogen separation tank 72a and the hydrogen supply port with a pipe.
- the filled mobile cylinder can be connected to the above hydrogen supply port and injected from the cylinder.
- an electric circuit including an electrolytic cell and an electrolytic power supply (rectifier) 74 is formed in the electrolytic device 70, it is preferable to shut off the electric circuit in the stopping step.
- the reverse current generated in the cathode 2c in the stop step can be reduced. Specifically, it can be cut off by using a circuit breaker, a disconnector, a switch, or a diode that blocks a reverse current.
- the electrolytic device 70 when the electrolytic device 70 includes a plurality of elements 60 having an anode 2a, a cathode 2c, a partition wall 1 for separating the anode 2a and the cathode 2c, and an outer frame 3 for edging the partition wall 1. It is preferable that the plurality of elements 60 are overlapped with each other sandwiching the diaphragm 4 in a state of being insulated from each other. By doing so, the elements 60 are isolated from each other, so that it is possible to prevent the electric charge accumulated in each element 60 in the energization process from affecting the other elements 60 in the stop process. Can be done.
- the method of making the plurality of elements 60 insulated from each other is preferably in a state of being insulated between the outer frames 3 of the elements 60, and specifically, for example, between the elements 60. This can be done by improving the insulating property of the gasket 7 arranged in. Further, the insulation here preferably means that the insulation resistance between the elements 60 is 1 M ⁇ or more. Alternatively, the gasket 7 can be covered with an insulating resin sheet (for example, a fluororesin such as polytetrafluoroethylene).
- the amount of electric charge held by the cathode 2c is preferably 0.1 times or less the amount of electric charge held by the anode 2a.
- the above-mentioned operation method can be more preferably applied.
- the amount of electric charge held by the cathode 2c is the amount of hydrogen gas controlled based on the amount of electric charge (C) held by the cathode chamber 5c when the electrolysis of the electrolytic solution in the energizing process is stopped (at the end of the energizing process). It is the amount of electric charge possessed by the cathode 2c.
- the amount of charge (C) possessed by the cathode 2c is determined by passing a positive current through the cathode 2c to sufficiently reduce it, then stopping the positive current and measuring the potential of the cathode 2c while passing a reverse current.
- the time-integrated value of the reverse current until the potential of the cathode 2c becomes equal to the potential of the anode 2a is defined as the possessed charge amount of the cathode 2c.
- the retained charge amount (c) of the anode 2a can be measured in the same manner as the possessed charge amount of the cathode 2c.
- the material of the anode 2a or the cathode 2c may be appropriately selected. It can be carried out.
- the electrolytic device 70 having the configuration shown in FIG. 1 can be manufactured by using the components of the electrolytic device 70 described above, but the present invention is not limited thereto.
- the above-mentioned effect becomes remarkable by using a variable power source such as solar power or wind power.
- Example 1 In an alkaline water electrolysis system including a large electrolytic cell 50 in which a plurality of large electrolytic cells having an electrode area of about 3 square meters are stacked, an electrolytic solution circulation pump 71, and a heat exchanger 79, the electrolytic solution is circulated every hour after the energization is stopped.
- the liquid level height control means 30 is instructed to do so.
- the time change graph of the liquid level is illustrated in FIG. When the energization is stopped, the temperature of the electrolytic solution decreases with time because the heat generation source disappears, and as a result of the increase in the density of the electrolytic solution, the liquid level gradually decreases.
- the liquid level can be recovered before the liquid level reaches the lower limit.
- the upper limit of the liquid level (that is, the liquid level) represents the upper end of the electrode chamber, and the lower limit is a position 50 mm vertically downward from the uncoated upper end 4t.
- Example 2 In an alkaline water electrolysis system including a large electrolytic cell 50 in which a plurality of large electrolytic cells having an electrode area of about 3 square meters are stacked, an electrolytic solution circulation pump 71, and a heat exchanger 79, each time the temperature drops by 5 ° C from the electrolytic solution temperature when energization is stopped.
- the liquid level height control means 30 is instructed to carry out the electrolytic liquid circulation.
- a time-lapse graph of the electrolyte temperature is illustrated in FIG.
- the liquid level can be recovered before the liquid level reaches the lower limit.
- the gas dissolved in the electrolytic solution may promote gas mixing, which is not preferable.
- Example 3 In an alkaline water electrolysis system including a large electrolytic cell 50 in which a plurality of large electrolytic cells having an electrode area of about 3 square meters are stacked, an electrolytic solution circulation pump 71, and a heat exchanger 79, the pressure of each part while the electrolytic solution circulation is stopped is calculated by the following formula.
- the anode liquid head pressure La [kPa] and the cathode liquid head pressure Lc [kPa] are obtained.
- ⁇ a anodic electrolyte density [kg / m 3 ]
- ⁇ c anolyte electrolyte density [kg / m 3 ]
- g gravitational acceleration [m / s 2 ].
- the electrolyte density is generally temperature-dependent, it is necessary to correct it.
- Ha or Hc reaches a predetermined value by calculation from the pressure difference while the electrolytic solution is stopped, the liquid level is lowered to the lower limit by instructing the liquid level height control means 30 to execute the electrolytic solution circulation. The liquid level can be restored before reaching.
- Example 4 In an alkaline water electrolysis system including a large electrolytic cell 50 in which a plurality of large electrolytic cells having an electrode area of about 3 square meters are stacked, an electrolytic cell circulation pump 71, and a heat exchanger 79, the distance between the electrodes of the electrolytic cell during energization and electrolytic cell circulation stoppage. By providing a means for measuring the resistance value, the average liquid level height in the electrolytic cell is evaluated. Since the electrolytic solution is a good conductor and the resistance values of other paths are relatively negligible, the average liquid level height L [m] and the electric resistance value R [ ⁇ ] have the following relationship.
- the present invention it is possible to suppress deterioration of the anode and cathode that may occur when electrolysis is stopped under a variable power source such as solar power or wind power.
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Abstract
Description
再生可能エネルギーは、出力が気候条件に依存するため、その変動が非常に大きいという性質がある。そのため、再生可能エネルギーによる発電で得られた電力を一般電力系統に輸送することが常に可能とはならず、電力需給のアンバランスや電力系統の不安定化等の社会的な影響が懸念されている。
そこで、再生可能エネルギーから発電された電力を、貯蔵及び輸送が可能な形に代えて、これを利用しようとする研究が行われている。具体的には、再生可能エネルギーから発電された電力を利用した水の電気分解(電解)により、貯蔵及び輸送が可能な水素を発生させ、水素をエネルギー源や原料として利用することが検討されている。
水素は、石油精製、化学合成、金属精製等の場面において、工業的に広く利用されており、近年では、燃料電池車(FCV)向けの水素ステーションやスマートコミュニティ、水素発電所等における利用の可能性も広がっている。このため、再生可能エネルギーから特に水素を得る技術の開発に対する期待は高い。
水の電気分解の方法としては、固体高分子型水電解法、高温水蒸気電解法、アルカリ水電解法等があるが、数十年以上前から工業化されていること、大規模に実施することができること、他の水電解システムに比べると安価であること等から、アルカリ水電解は特に有力なものの一つとされている。
しかしながら、アルカリ水電解を今後エネルギーの貯蔵及び輸送のための手段として適応させるためには、前述のとおり出力の変動が大きい電力を効率的且つ安定的に利用して水電解を行うことを可能にする必要があり、アルカリ水電解用の電解セルや装置の諸課題を解決することが求められている。
例えば、アルカリ水電解において電解電圧を低く抑えて、水素製造の電力原単位を改善するという課題を解決するためには、電解セルの構造として、特に、隔膜と電極との隙間を実質的に無くした構造である、ゼロギャップ構造と呼ばれる構造を採用することが有効なことはよく知られている(特許文献1、2参照)。ゼロギャップ構造では、発生するガスを電極の細孔を通して電極の隔膜側とは反対側に素早く逃がすことによって、電極間の距離を低減しつつ、電極近傍におけるガス溜まりの発生を極力抑えて、電解電圧を低く抑制している。ゼロギャップ構造は、電解電圧の抑制にきわめて有効であり、種々の電解装置に採用されている。
しかしながら、特許文献1は、電解槽へ通電している稼働中の漏洩電流の発生を防ぐことを目的としており、通電停止時及び再起動時については何ら記載していない。
[1]
隔膜を挟んで陽極と陰極とが重ねあわされた電解セルを含む電解槽、及び
前記電解槽への通電停止時に稼働する、前記電解セル内の電解液の液面高さを調整する液面高さ制御手段を含む、ことを特徴とする電解システム。
[2]
前記液面高さ制御手段が、前記液面高さを前記隔膜の非被覆上端より鉛直方向上方に制御する手段である、[1]に記載の電解システム。
[3]
前記液面高さ制御手段が、電解液循環ポンプである、[1]又は[2]に記載の電解システム。
[4]
前記液面高さ制御手段が稼働する時間が、通電停止の時間100%に対して、0%超20%以下である、[1]~[3]のいずれかに記載の電解システム。
[5]
前記液面高さ制御手段が、通電停止時間に応じて液面高さを調整する、[1]~[4]のいずれかに記載の電解システム。
[6]
前記液面高さ制御手段が、電解液温度に応じて液面高さを調整する、[1]~[5]のいずれかに記載の電解システム。
[7]
前記液面高さ制御手段が、電解液の液頭圧に応じて液面高さを調整する、[1]~[6]のいずれかに記載の電解システム。
[8]
前記液面高さ制御手段が、電気抵抗値に応じて液面高さを調整する、[1]~[7]のいずれかに記載の電解システム。
[9]
前記液面高さ制御手段が、電解セル中の電解液の液面高さに応じて液面高さを調整する、[1]~[8]のいずれかに記載の電解システム。
[10]
前記液面高さ制御手段が、電解液の前記液面高さが、前記隔膜の非被覆上端よりも鉛直方向下方に位置した場合に、送液ポンプにより電解液を電解セル内に注入する手段である、[9]に記載の電解システム。
[11]
アルカリ水電解用である、[1]~[10]のいずれかに記載の電解システム。
[12]
[1]~[11]のいずれかに記載の電解システムの使用方法。
[13]
相互に隔膜で区画された、陽極を有する陽極室と陰極を有する陰極室とを備える電解装置の運転方法であって、
前記陽極室及び前記陰極室中の電解液の電気分解が行われる通電工程と、
前記陽極室及び前記陰極室中の電解液の電気分解が停止している停止工程と、を有し、
前記停止工程において、前記陽極室及び/又は前記陰極室内の前記電解液の液面が前記隔膜の非被覆上端よりも鉛直方向上方に位置することを特徴とする、電解装置の運転方法。
[14]
前記停止工程において、前記陽極室及び前記陰極室内の前記電解液の液面を測定する液面計によりそれぞれの当該液面を監視し、当該陽極室及び当該陰極室内の当該液面が前記隔膜の非被覆上端よりも鉛直方向下方に位置した場合に、送液ポンプにより前記電解液を前記陽極室及び/又は前記陰極室内に注入し、前記陽極室及び/又は前記陰極室の液面を前記隔膜の非被覆上端よりも鉛直方向上方に位置させる、[13]に記載の電解装置の運転方法。
[15]
前記停止工程において、送液ポンプを連続的又は間欠的に稼働し、前記陽極室及び/又は前記陰極室の液面を前記隔膜の非被覆上端よりも鉛直方向上方に位置させる、[13]又は[14]に記載の電解装置の運転方法。
[16]
前記電解装置が、当該電解装置の電解槽よりも鉛直方向上方に位置する、前記電解液を貯留する貯留タンクを有し、
前記停止工程において、重力を利用して前記貯留タンク内の前記電解液を前記陽極室及び/又は前記陰極室に注入し、前記陽極室及び/又は前記陰極室の液面を前記隔膜の非被覆上端よりも鉛直方向上方に位置させる、[13]~[15]のいずれかに記載の電解装置の運転方法。
[17]
前記陰極の少なくとも一部が、前記隔膜の非被覆上端よりも鉛直方向上方に存在する、[13]~[16]のいずれかに記載の電解装置の運転方法。
電解システム70は、電解槽50を含む。さらに液面高さ制御手段30を含んでいてもよい。また、さらに、供給電源74、電解液を循環させるための送液ポンプ71、電解液と気体(例えば、水素、酸素等)とを分離する気液分離タンク72(陽極ガス分離タンク72a、陰極ガス分離タンク72c)、電解により消費した水を補給するための水補給器73、濃度計、流量計77、圧力計78、熱交換器79、配管81、圧力制御弁80等を含んでいてよい。なお、液面高さ制御手段30が電解液循環ポンプである場合、液面高さ制御手段としての機能も備えた送液ポンプ71を用いてもよいし、送液ポンプ71とは異なるポンプを用いてもよい。
図1の矢印は、電解液又は気体が流れる方向である。
上記電解槽は、少なくとも1つの電極エレメントが接続された、単極式であってもよいし、複極式であってもよい。
例えば、複極式は、多数の電極エレメントを直列に接続して電源に接続する方法の1つであり、片面が陽極2a、片面が陰極2cとなる複数の複極式エレメント60を、隔膜4を挟んで同じ向きに並べて直列に接続し、両端のみを電源に接続する方法である(図2)。上記電解槽としては、例えば、隣り合う2つのエレメント(例えば、陽極ターミナルエレメント51a、複極式エレメント60、及び陰極ターミナルエレメント51cのうちの隣り合う2つのエレメント等)において、隔膜4を挟んで一方のエレメントの陽極2aと他方のエレメントの陰極2cとを重ね合わせて並べる構造を少なくとも1つ有する電解槽が挙げられる。隔膜4は、電解槽内の全ての隣り合う2つのエレメント間に設けられていることが好ましい。
複極式電解槽は、電源の電流を小さくできるという特徴を持ち、電解により化合物や所定の物質等を短時間で大量に製造することができる。電源設備は出力が同じであれば、低電流、高電圧の方が安価でコンパクトになるため、工業的には単極式よりも複極式の方が好ましい。
図2に示す電解槽50は、複極式電解槽である。複極式電解槽は、エレメント60(例えば複極式エレメント)を必要数積層することで構成されていてよい。
電解槽50は、一端からファストヘッド51h、絶縁板51i、陽極ターミナルエレメント51aが順番に並べられ、更に、陽極側ガスケット部分7、隔膜4、陰極側ガスケット部分7、エレメント60(例えば、複極式エレメント)が、この順番で並べて配置される。このとき、エレメント60は陽極ターミナルエレメント51a側に陰極2cを向けるよう配置する。陽極側ガスケット部分7からエレメント60までは、設計生産量に必要な数だけ繰り返し配置される。陽極側ガスケット部分7からエレメント60までを必要数だけ繰り返し配置した後、再度、陽極側ガスケット部分7、隔膜4、陰極側ガスケット部分7を並べて配置し、最後に陰極ターミナルエレメント51c、絶縁板51i、ルーズヘッド51gをこの順番で配置される。電解槽50は、全体をタイロッド方式51r(図2参照)や油圧シリンダー方式等の締め付け手段により締め付けることにより一体化される。
エレメント60は、陽極2aと、陰極2cと、陽極2aと陰極2cとを隔離する隔壁1と、隔壁1を縁取る外枠3とを備えている。隔壁1は導電性を有していてよく、外枠3は隔壁1の外縁に沿って隔壁1を取り囲むように設けられていてよい。各エレメント60は、隔膜4を挟んで重ね合わせられている。
電解槽を構成する配置は、陽極2a側からでも陰極2c側からでも任意に選択でき、上述の順序に限定されるものではない。
なお、本明細書において、一例として、複極式エレメント等を含む複極式電解槽として説明する場合があるが、本発明は複極式電解槽に限定されるものではない。
なお、図2、3に示した例では、長方形形状の隔壁1と長方形形状の隔膜4とが平行に配置され、また、隔壁1の端縁に設けられた直方体形状の外枠3の隔壁1側の内面が隔壁1に垂直となっているため、電極室5の形状が直方体状となっている。
電解セル65において、隣り合うエレメント60等で挟まれる部分は、隔膜4と非通気性膜とを設けてもよい。例えば、陽極2aと陰極2cとで挟まれた部分は、イオン透過性の隔膜4とし、隔膜よりも外枠3側に、イオン、ガス、電解液を透過させない非通気性膜を用いてもよい。
また、電極室の鉛直方向下側に、陽極室に電解液を供給する陽極用配液管、陰極室に電解液を供給する陰極用配液管を備えていてよく、鉛直方向上側に、陽極室から電解液を排出する陽極用集液管20ao、陰極室から電解液を排出する陰極用集液管20coを備えていてよい。
電極室5は、外枠3との境界において、電極室5に電解液を導入する電解液入口5iと、電極室5から電解液を導出する電解液出口5oとを有していてよい(図5、6)。より具体的には、陽極室5aには、陽極室5aに電解液を導入する陽極電解液入口5aiと、陽極室5aから導出する電解液を導出する陽極電解液出口5aoとが設けられる。同様に、陰極室5cには、陰極室5cに電解液を導入する陰極電解液入口5ciと、陰極室5cから導出する電解液を導出する陰極電解液出口5coとが設けられていてよい。
また、一例の電解槽50では、整流板6は、電極室5の高さとほぼ同じ長さを有し、隔壁1に垂直に設けられており、電解液通過方向について所定のピッチで貫通孔を有している。
本実施形態の電解システムは、液面高さ制御手段30を含むことが好ましい。
ここで、図4を用いて、通電停止状態の電解槽について説明する。
電解槽50の通電及び電解液の循環が停止すると、電極室の鉛直上方に電極から発生したガスが貯留した状態となる(図4(a))。このまま通電停止状態が続くと、運転温度から温度が低下し、電解液密度が増加する結果、徐々に電解槽内の電解液レベルが低下し、ガスと電解液との界面(液面31、喫水線L)が、陽極と陰極とを隔てる隔膜4の上端(電解室内に露出している隔膜4の上端、非被覆上端4t)よりも低くなることがある(図4(b))。ここで、貯留したガスが、一方の電極室から他方の電極室に拡散する速度は、液面31(喫水線L)が電解室内に露出している透過性の隔膜4よりも上側にある場合(図4(a))に比べ、隔膜4が露出すると格段に速くなる(図4(b))。ガスが他方の電極室に拡散すると、ガスの混合が進み、ガスの純度が低下し、また、ガスの爆発性が増すことによって安全性が低下する。
本実施形態の電解システムでは、上記液面高さ制御手段30が、通電停止時に稼働するため、液面31を電解室内に露出している隔膜4の上端より鉛直方向上方等に制御できるため、ガスの混合を抑制することができる。また、液面を高く維持することで、再稼働に要する時間を短くすることができる。
上記液面高さ制御手段は、液面高さを隔膜の非被覆上端より鉛直方向上方に制御する手段であることが好ましい。なお、被覆上端より鉛直方向上方に制御するとは、液面高さが常に非被覆上端より鉛直上方にあることだけでなく、液面高さが非被覆上端より低くなった後に液面高さを非被覆上端より鉛直上方まで回復させることを含む。
なお、図1において、送液ポンプ71とは別に液面高さ制御手段30を設ける例を記載したが、例えば、上記トリガーからの入力に応じて送液量を変動できる一つのポンプを用いてもよいし、上記トリガーからの入力に応じて流量を調整する弁を用いてもよい。
また、再起動に要する時間をより一層短縮できる観点から、上記上限は、電極室から電解液が排出する管(例えば、内部ヘッダー型の陽極用集液管20ao、陰極用集液管20co)が電解液に満たされている位置であることが好ましい。なお、隔膜が露出しない液面高さであれば、例えば、集液管の鉛直上端から10mmの位置を上限としてもよいし、100mmの位置を上限としてもよい。
上記液面高さ制御手段は、電極室中の電解液の液面高さが、隔膜の非被覆上端よりも鉛直方向下方に位置した場合に、送液ポンプにより電解液を電解セル内(例えば、液面高さが低下した電極室内)に注入する手段であることが好ましい。
上記電解液温度としては、前回の液面高さ制御手段30を稼働させたときの電解液温度から10℃低くなった時点で液面高さ制御手段30を稼働させることが好ましく、5℃低くなった時点で稼働させることがより好ましい。なお、通電停止後の液面高さ制御手段の最初の制御を、電解液温度をトリガーとして行う場合、通電停止時の電解液温度から上記温度低下したときに稼働させて良い。
上限としては、液面が電極室上端にある時の液頭圧が好ましく、下限としては、隔膜上端(例えば、電極室に露出している隔膜の上端、非被覆上端4t)から鉛直下方に100mm以内の位置であるときの液頭圧がより好ましく、隔膜上端から10mm以内の位置である時の液頭圧がさらに好ましく、隔膜上端であるときの液頭圧が特に好ましい。陽極室と陰極室とで異なる上限と下限を設定してもよい。
例えば、上記液面高さ制御手段は、上記液面高さが、鉛直方向に隔膜上端となったときに稼働することが好ましく、隔膜上端から鉛直下方に100mm以内となったときに稼働することがより好ましく、隔膜上端から10mm以内の位置となったときに稼働することがさらに好ましく、隔膜上端未満の位置となったときに稼働することが特に好ましい。
電解槽50は、電極と隔膜との隙間に電解で発生したガスが滞留しにくくなり、ガスが混合しにくくなり、また電気抵抗を低くして効率的な電解反応が可能となる観点から、隔膜4が陽極2a及び陰極2cと接触してゼロギャップ構造Zを形成してもよい(図3)。
なお図3、4では、陽極2a、隔膜4、陰極2cとの間に隙間を設けているが、ゼロギャップ構造Zでは隙間がないことが好ましい。電解セルにおいて、隔膜4と、陽極2aや陰極2cとの間に隙間がある場合、この部分には電解液の他に電解で発生した大量の気泡が滞留することで、電気抵抗が非常に高くなる。また、通電停止時にガスが混合しやすくなる。電解セル65における大幅な電解電圧の低減を図るためには、陽極2aと陰極2cの間隔(以下、「極間距離」ともいう。)をできるだけ小さくして、陽極2aと陰極2cの間に存在する電解液や気泡の影響をなくすことが効果的である。電極全面にわたり、陽極2aと隔膜4とが互いに接触し、且つ、陰極2cと隔膜4とが互いに接触している状態、又は、電極全面にわたり、極間距離が隔膜4の厚みとほぼ同じとなる距離で、上記隙間のほとんど無い状態、に保つことのできる、ゼロギャップ構造Zが採用される。
極間距離を小さくするための手段は、例えば、陽極2aと陰極2cを完全に平滑に加工して、隔膜4を挟むように押し付ける方法や、電極2と隔壁1との間にバネ等の弾性体を配置し、この弾性体で電極2を支持する方法が挙げられる。例えば、隔壁1に導電性の材料で製作されたバネを取り付け、このバネに電極2を取り付けてよい。また、隔壁1に取り付けた電極リブにバネを取り付け、そのバネに電極2を取り付けてよい。なお、このような弾性体を用いた形態を採用する場合には、電極2が隔膜4に接する圧力が不均一にならないように、バネの強度、バネの数、形状等必要に応じて適宜調節する必要がある。
電解槽50は、50~500のエレメント60(例えば、複極式エレメント)を有することが好ましく、70~300のエレメント60を有することがさらに好ましく、100~200のエレメント60を有することが特に好ましい。
なお、複数のエレメント60が相互に絶縁された状態になるとは、具体的には、エレメント60の外枠3間で絶縁された状態となることが好ましく、例えば、エレメント60間に配置するガスケット7の絶縁性を高める等により行うことができる。また、ここでの絶縁とは、エレメント60間で、絶縁抵抗が1MΩ以上であることが好ましい。
電解槽に取り付けられるヘッダーの配設態様として、代表的には、内部ヘッダー型と外部ヘッダー型とがあるが、いずれの型を採用してもよい。
電解セル65は、複数の電解セル65に共通するヘッダー10と呼ばれる電解液の給排配管と繋がっている。一般に、陽極用配液管は陽極入口ヘッダー、陰極用配液管は陰極入口ヘッダー、陽極用集液管は陽極出口ヘッダー、陰極用集液管は陰極出口ヘッダーと呼ばれる。電解セル65はホース等を通じて各電極用配液管及び各電極用集液管と繋がっている。
外部ヘッダー型の場合、電解槽50は、外枠3の外方に、電極室5に連通するヘッダー10を備えていてよい(図5、図6参照)。
一例では、隔壁1の端縁にある外枠3の下方に、陽極室5aに電解液を入れる陽極入口ヘッダー10Oaiと、陰極室5cに電解液を入れる陰極入口ヘッダー10Ociとを備えており、また、同様に、隔壁1の端縁にある外枠3の側方に、陽極室5aから電極液を出す陽極出口ヘッダー10Oaoと、陰極室5cから電解液を出す陰極出口ヘッダー10Ocoとを備えている。
また、一例では、陽極室5a及び陰極室5cにおいて、入口ヘッダーと出口ヘッダーとが、電極室5の中央部を挟んで向かい合うように設けられている。
図6に、外部ヘッダー型の電解装置の電解槽の一例について平面図で示す。
一例では、外枠3のうちの下方に、陽極入口ヘッダー10Oaiに連通する陽極用配液管20Oaiと、陰極入口ヘッダー10Ociに連通する陰極用配液管20Ociとを備えており、また、同様に、外枠3のうちの側方に、陽極出口ヘッダー10Oaoに連通する陽極用集液管20Oaoと、陰極出口ヘッダー10Ocoに連通する陰極用集液管20Ocoとを備えている。
また、通常、陽極用配液管20Oai、陰極用配液管20Oci、陽極用集液管20Oao、陰極用集液管20Ocoは、各電極室5に1つずつ設けられるが、これに限定されず、複数の電極室5で兼用されてもよい。
気液分離ボックスの表面は、電解液の腐食性や、圧力や温度等の運転条件に十分耐えうる材質のコーティング材料で、被覆されていても良い。コーティング材料の材質は、電解槽内部での漏洩電流回路の電気抵抗を大きくする目的で、絶縁性のものを採用してもよい。コーティング材料の材質に、EPDM、PTFE、ETFE,PFA、ポリ塩化ビニル、ポリエチレン等を採用してもよい。
アルカリ水電解による水素製造等の電解において、エネルギー消費量の削減、具体的には電解電圧の低減は、大きな課題である。この電解電圧は電極2に大きく依存するため、両電極2の性能は重要である。
平織メッシュを用いる場合、寸法は特に制限されないが、電解表面積増加によるガス発生量の増加と、電解により発生するガスの電極表面からの効率的な除去を両立させるために、線径は0.05mm以上1.0mm以下、ピッチは20メッシュ以上60メッシュ以下、開口率は30%以上70%以下が好ましい。より好ましくは、線径は0.1mm以上0.3mm以下、ピッチは30メッシュ以上50メッシュ以下、開口率は40%以上60%以下である。
パンチングメタルを用いる場合、寸法は特に制限されないが、電解表面積増加によるガス発生量の増加と、電解により発生するガスの電極表面からの効率的な除去を両立させるため、また、機械的強度の観点から、孔径は2mm以上8mm以下、ピッチは2mm以上10mm以下、開口率は20%以上80%以下、厚みは0.5mm以上2mm以下が好ましい。
エキスパンドメタルを用いる場合、寸法は特に制限されないが、電解表面積増加によるガス発生量の増加と、電解により発生するガスの電極表面からの効率的な除去を両立させるため、また、機械的強度の観点から、メッシュの短目方向の中心間距離(SW)は2mm以上5mm以下、メッシュの長目方向の中心間距離(LW)は3mm以上10mm以下、厚みは0.5mm以上2mm以下、開口率は20%以上80%以下が好ましい。より好ましくは、SWは3mm以上4mm以下、LWは4mm以上6mm以下、厚みは0.8mm以上1.5mm以下、開口率は40%以上60%以下である。
金属発泡体を用いる場合、寸法は特に制限されないが、電解表面積増加によるガス発生量の増加と、電解により発生するガスの電極表面からの効率的な除去を両立させるため、また、機械的強度の観点から、気孔率は80%以上95%以下、厚みは0.5mm以上2.0mm以下が好ましい。
また、陰極の触媒層は、水素発生能が高いことが好ましく、ニッケル、コバルト、鉄、又は白金族元素等を用いることができる。
隔壁1の材料としては、電力の均一な供給を実現する観点から、導電性を有する材料が好ましく、耐アルカリ性や耐熱性といった面から、ニッケル、ニッケル合金、軟鋼、ニッケル合金上にニッケルメッキを施したものが好ましい。
特に、隔壁1が板状の形状である場合、隔壁1の厚さは、0.5mm~5mmとしてよく、縦の長さや横の長さは、特に限定されない。
隔壁1の形状は、所定の厚みを有する板状の形状としてよいが、特に限定されない。
なお、隔壁1は、通常、隔壁1に沿う所与の方向D1が、鉛直方向となるように、使用してよく、具体的には、図5、図6に示すように隔壁1の平面視形状が長方形である場合、隔壁1に沿う所与の方向D1が、向かい合う2組の辺のうちの1組の辺の方向と同じ方向となるように、使用してよい。
上記外枠3の形状は、隔壁1を縁取ることができる限り特に限定されないが、隔壁1の平面に対して垂直な方向に沿う内面を隔壁1の外延に亘って備える形状としてよい。
外枠3の形状としては、特に限定されることなく、隔壁1の平面視形状に合わせて適宜定められてよい。
外枠3の寸法としては、特に限定されることなく、電極室5の外寸に応じて設計されてよい。外枠3の幅は、10mm~40mmとしてよく、15mm~30mmが好ましく、外枠3の延在長さは、特に限定されない。
この場合の陽極フランジ部及び陰極フランジ部の長さとしては、特に限定されないが、それぞれ、5mm~20mmとしてよく、7.5mm~15mmが好ましい。
上記隔膜4としては、イオンを導通しつつ、発生するガス(例えば、アルカリ水電解の場合は水素ガスと酸素ガス)を隔離するために、イオン透過性の隔膜4が使用することが好ましい。このイオン透過性の隔膜4としては、イオン交換能を有するイオン交換膜、電解液を浸透することができる多孔膜等を用いることができる。このイオン透過性の隔膜4は、ガス透過性が低く、イオン伝導率が高く、電子電導度が小さく、強度が強いものが好ましい。
アルカリ水電解用電解槽において用いられる隔膜4としては、ポリスルホン系隔膜が好ましい。
多孔膜は、複数の微細な貫通孔を有し、隔膜4を電解液が透過できる構造を有する。電解液が多孔膜中に浸透することにより、イオン伝導を発現するため、孔径や気孔率、親水性といった多孔構造の制御が非常に重要となる。一方、電解液だけでなく、発生ガスを通過させないこと、すなわちガスの遮断性を有することが求められる。この観点でも多孔構造の制御が重要となる。
多孔膜は、複数の微細な貫通孔を有するものであるが、高分子多孔膜、無機多孔膜、織布、不織布等が挙げられる。これらは公知の技術により作製することができる。高分子多孔膜の製法例としては、相転換法(ミクロ相分離法)、抽出法、延伸法、湿式ゲル延伸法等が挙げられる。
多孔膜は、高分子材料と親水性無機粒子とを含むことが好ましく、親水性無機粒子が存在することによって多孔膜に親水性を付与することができる。
高分子材料として、ポリスルホン、ポリエーテルスルホン、ポリフェニルスルホンを用いることで、高温、高濃度のアルカリ溶液に対する耐性が一層向上する。ポリスルホン、ポリエーテルスルホン、ポリフェニルスルホンは架橋処理が施されていてもよい。かかる架橋処理が施されたポリスルホン、ポリエーテルスルホン、ポリフェニルスルホンの重量平均分子量は、標準ポリスチレン換算の重量平均分子量として、4万以上15万以下であることが好ましい。架橋処理の方法は、特に限定されないが、電子線やγ線等の放射線照射による架橋や架橋剤による熱架橋等が挙げられる。なお、標準ポリスチレン換算の重量平均分子量はGPCで測定することができる。
上記した高分子材料は、市販品を用いることもできる。ポリスルホンとしては、例えば、BASF社の「Ultrason S PSU(登録商標、以下同様)」、ソルベイアドバンストポリマーズ社の「ユーデル(登録商標、以下同様)」等が挙げられる。ポリエーテルスルホンとしては、例えば、BASF社の「Ultrason E PES(登録商標、以下同様)」、ソルベイアドバンストポリマーズ社の「レーデル A(登録商標、以下同様)」等が挙げられる。ポリフェニルスルホンとしては、例えば、BASF社の「Ultrason P PPSU(登録商標、以下同様)」、ソルベイアドバンストポリマーズ社の「レーデル R(登録商標、以下同様)」等が挙げられる。ポリフェニレンサルファイドとしては、例えば、東レ社の「トレリナ(登録商標、以下同様)」等が挙げられる。ポリテトラフルオロエチレンとしては、三井デュポンフロロケミカル社の「テフロン(登録商標、以下同様)」、ダイキン社の「ポリフロン(登録商標、以下同様)」、旭硝子社の「フロオン(登録商標、以下同様)」等が挙げられる。
多孔膜の平均孔径が大きいほど、単位面積あたりの多孔膜透過量は大きくなり、特に、電解においては多孔膜のイオン透過性が良好となり、電圧損失を低減しやすくなる傾向にある。また、多孔膜の平均孔径が大きいほど、アルカリ水との接触表面積が小さくなるので、ポリマーの劣化が抑制される傾向にある。
一方、多孔膜の平均孔径が小さいほど、多孔膜の分離精度が高くなり、電解においては多孔膜のガス遮断性が良好となる傾向にある。さらに、後述する粒径の小さな親水性無機粒子を多孔膜に担持した場合、欠落せずしっかりと保持することができる。これにより、親水性無機粒子が持つ高い保持能力を付与でき、長期に亘ってその効果を維持することができる。
平均孔径は、0.1μm以上1.0μm以下、かつ/又は、最大孔径は0.1μmよりも大きく2.0μm以下の範囲であることが好ましい。多孔膜は、孔径がこの範囲であれば、優れたガス遮断性と高いイオン透過性とを両立することができる。また、多孔膜の孔径は実際に使用する温度域において制御されることが好ましい。従って、例えば90℃の環境下での電解用隔膜4として使用する場合は、90℃で上記の孔径の範囲を満足させることが好ましい。また、多孔膜は、アルカリ水電解用隔膜4として、より優れたガス遮断性と高いイオン透過性とを発現できる範囲として、平均孔径が0.1μm以上0.5μm以下、かつ/又は、最大孔径が0.5μm以上1.8μm以下であることがより好ましい。
多孔膜の平均孔径とは、完全性試験機(ザルトリウス・ステディム・ジャパン社製、「Sartocheck Junior BP-Plus」)を使用して以下の方法で測定した平均透水孔径をいう。まず、多孔膜を芯材も含めて所定の大きさに切り出して、これをサンプルとする。このサンプルを任意の耐圧容器にセットして、容器内を純水で満たす。次に、耐圧容器を所定温度に設定した恒温槽内で保持し、耐圧容器内部が所定温度になってから測定を開始する。測定が始まると、サンプルの上面側が窒素で加圧されていき、サンプルの下面側から純水が透過してくる際の圧力及び透過流量の数値を記録する。平均透水孔径は、圧力が10kPaから30kPaの間の圧力と透水流量との勾配を使い、以下のハーゲンポアズイユの式から求めることができる。
平均透水孔径(m)={32ηLμ0/(εP)}0.5
ここで、ηは水の粘度(Pa・s)、Lは多孔膜の厚み(m)、μ0は見かけの流速であり、μ0(m/s)=流量(m3/s)/流路面積(m2)である。また、εは空隙率、Pは圧力(Pa)である。
最大孔径(m)=4γcosθ/P
ここで、γは水の表面張力(N/m)、cosθは多孔膜表面と水の接触角(rad)、Pはバブルポイント圧力(Pa)である。
ガス遮断性や低電圧損失等を高いレベルで両立させるといった観点から、多孔膜の気孔率の下限は30%以上であることが好ましく、35%以上であることがより好ましく、40%以上であることが更に好ましい。また、気孔率の上限は65%以下であることが好ましく、60%以下であることがより好ましく、55%以下であることが更に好ましい。多孔膜の気孔率が上記上限値以下であれば、膜内をイオンが透過しやすく、膜の電圧損失を抑制できる。
気孔率P(%)=ρ/(1+ρ)×100
ここで、ρ=(W3-W1)/(W3-W2)であり、W1は多孔膜の乾燥質量(g)、W2は多孔膜の水中質量(g)、W3は多孔膜の飽水質量(g)である。
多孔膜の厚みが、上記下限値以上であれば、一層優れたガス遮断性が得られ、また、衝撃に対する多孔膜の強度が一層向上する。また、突刺し等で破れにくく、電極間がショートしにくい。また、ガス遮断性が良好となる。この観点より、多孔膜の厚みの下限は、300μm以上であることがより好ましく、350μm以上であることが更に好ましく、400μm以上でることがより一層好ましい。一方で、多孔膜の厚みが、上記上限値以下であれば、運転時に孔内に含まれる電解液の抵抗によりイオンの透過性を阻害されにくく、一層優れたイオン透過性を維持することができる。また、上記上限値以下であると、電圧損失が増大しにくい。また、多孔膜の厚みのばらつきによる影響が少なくなる。かかる観点から、多孔膜の厚みの上限は、600μm以下であることがより好ましく、550μm以下であることが更に好ましく、500μm以下であることがより一層好ましい。特に、高分子樹脂が、ポリスルホン、ポリエーテルスルホン及びポリフェニルスルホンからなる群より選ばれる少なくとも1種を含むものである場合に、かかる効果は一層向上する。
親水性無機粒子のモード粒径は、親水性無機粒子が多孔膜孔内に存在しているときの二次粒子の状態のものであり、粒子径分布の極大値の粒子径である。モード粒径は、以下の方法によって測定できる。高分子樹脂を溶解可能な溶媒を用いて、多孔膜から高分子樹脂を溶解除去する。その後に残った親水性無機粒子を、親水性無機粒子の重量の1000倍以上の量の当該溶媒を用いて、3回以上繰り返し洗浄する。洗浄した親水性無機粒子を測定試料として、レーザー回折・散乱法により、体積分布からモード粒径を計測する。親水性無機粒子のモード粒径は、例えば、レーザー回折・散乱式粒度分布測定装置(堀場製作所社製、「LA-950」)によって測定することができる。
イオン交換膜としては、カチオンを選択的に透過させるカチオン交換膜とアニオンを選択的に透過させるアニオン交換膜があり、いずれの交換膜でも使用することができる。
イオン交換膜の材質としては、特に限定されず、公知のものを用いることができる。例えば、含フッ素系樹脂やポリスチレン・ジビニルベンゼン共重合体の変性樹脂が好適に使用できる。特に耐熱性及び耐薬品性等に優れる点で、含フッ素系イオン交換膜が好ましい。
この当量質量EWは、イオン交換膜を塩置換し、その溶液をアルカリ又は酸溶液で逆滴定することにより測定することができる。当量質量EWは、原料であるモノマーの共重合比、モノマー種の選定等により調整することができる。
イオン交換膜の当量質量EWは、親水性、膜の耐水性の観点から300以上であることが好ましく、親水性、イオン交換能の観点から1300以下であることが好ましい。
電解槽50では、図3に示すように、隔壁1を縁取る外枠3同士の間に、隔膜4と共にガスケット7が挟持されることが好ましい。ガスケットは、エレメント60と隔膜4との間、エレメント60間を電解液と発生ガスに対してシールするために使用され、電解液や発生ガスの電解槽外への漏れや両電極室間におけるガス混合を防ぐことができる。
ゴム材料や樹脂材料としては、具体的には、天然ゴム(NR)、スチレンブタジエンゴム(SBR)、クロロプレンゴム(CR)、ブタジエンゴム(BR)、アクリロニトリル-ブタジエンゴム(NBR)、シリコーンゴム(SR)、エチレン-プロピレンゴム(EPT)、エチレン-プロピレン-ジエンゴム(EPDM)、フッ素ゴム(FR)、イソブチレン-イソプレンゴム(IIR)、ウレタンゴム(UR)、クロロスルホン化ポリエチレンゴム(CSM)等のゴム材料、ポリテトラフルオロエチレン(PTFE)やテトラフルオロエチレン・パーフルオロアルキルビニルエーテル共重合体(PFA)、テトラフルオロエチレン・エチレン共重合体(ETFE)、クロロトリフルオエチレン・エチレン共重合体(ECTFE)等のフッ素樹脂材料や、ポリフェニレンサルファイド(PPS)、ポリエチレン、ポリイミド、ポリアセタール等の樹脂材料を用いることができる。これらの中でも、弾性率や耐アルカリ性の観点でエチレン-プロピレン-ジエンゴム(EPDM)、フッ素ゴム(FR)が特に好適である。
このような補強材は公知の金属材料、樹脂材料及び炭素材料等が使用でき、具体的には、ニッケル、ステンレス等の金属、ナイロン、ポリプロピレン、PVDF、PTFE、PPS等の樹脂、カーボン粒子や炭素繊維等の炭素材料が挙げられる。
この場合、ガスケット7がスリット部を備える場合、スリット部のサイズはスリットの内寸が膜のサイズより縦横で0.5mm~5mm大きくなるようにするのがよい。
また、ガスケット7がスリット部を備える場合、スリット部の開口幅としては、膜の厚みの0.5倍~1.0倍としてよい。
なお、引張応力は、JIS K6251に準拠して、測定することができる。例えば、島津製作所社製のオートグラフAGを用いてよい。
電解槽50は、電解槽50の各電極室5a、5c内の液面を測定することができる液面計を有することが好ましい。当該液面計により、各電極室5a、5c内の液面を監視し(電極室5a、5c内での液面の高さを監視し)、各電極室5a、5c内の隔膜4の表面が電解液に対して浸漬状態であるか、又は浸漬していない非浸漬状態であるかを把握することができる。
液面計としては、特に限定されないが例えば、直視式、接触式、差圧式の液面計を用いることができる。
圧力計78は、電解槽内に設置してもよいし、電解槽外に設置してもよい。複数の電解セルを設ける場合は、全電解セルの一方の電極から排出されるガスをまとめて圧力を測定してよい。
上記送液ポンプ71としては、特に限定されず、適宜定められてよい。上記送液ポンプ71により、電解槽50中及び配管81を流れる電解液を循環させることができる。
送液ポンプ71として、陰極室5cへ送液するための陰極側送液ポンプ、陽極室5aへ送液するための陽極側送液ポンプを有することができ、それぞれ別々に稼働することができる。
上記気液分離タンク72は、電解液と電解槽で発生する気体とを分離するタンクであることが好ましく、電解槽の陽極で発生する気体と電解液とを分離する陽極側気液分離タンク72a及び電解槽の陰極で発生する気体と電解液とを分離する陰極側気液分離タンク72cであることが好ましい。
例えば、アルカリ水電解の場合、陽極で酸素、陰極で水素が発生する。この場合、上記陽極側気液分離タンク72aは酸素分離タンクであり、上記陰極側気液分離タンク72cは水素分離タンクである。陽極室5a用の気液分離タンク72は、陽極室5aで発生した酸素ガスと電解液を分離し、陰極室5c用の気液分離タンク72は、陰極室5cで発生した水素ガスと電解液を分離する。
循環停止時の電解槽中の液面の低下を防ぐ目的で、気液分離タンク72内の電解液面を電解槽上面よりも高いことが好ましいが、これに限定されるものではない。
電解セル65と気液分離タンク72との間に遮断弁を付けることが好ましいが、これに限定されるものではない。
また、タンク高さも同様に、高さが低い場合は、上記変動の影響を受けやすいため、高くすることが好ましい。
水補給器73としては、特に限定されず、適宜定められてよい。
水としては、一般上水を使用してもよいが、長期間に亘る運転を考慮した場合、イオン交換水、RO水、超純水等を使用することが好ましい。
電解装置70では、電解液を貯留する貯留タンクを有することができる。また、当該貯留タンクは、電解装置70の電解槽50よりも鉛直方向上方に位置することが好ましい。貯留タンクが電解槽50と配管等で接続することで、重力を利用して貯留タンク内の電解液を電解槽へ注入することができる。また当該配管等にバルブ等を設けることで流量を適切に調節することもできる。
上記配管81としては、特に限定されず、適宜定められてよい。
上記配管81は、電解液を電解槽50外へ流す配管である。例えば、図1に示すように、電解槽50と気液分離タンク72、気液分離タンク72と送液ポンプ71、送液ポンプ71と電解槽50とをつなぐことができる。
なお、気液分離タンク72で分離した気体と圧力計78、圧力制御弁80、濃度計は、気体用の管でつながれていることが好ましい。
上記供給電源は、直流電源であることが好ましい。
上記一定電源としては、グリッドを通して供給される電力の電力源、蓄電池電源等が挙げられる。グリッドを通して供給される電力源は、火力、原子力等の安定な電力源由来の電源であってもよいし、再生可能エネルギー出力由来等の変動電源と安定な電源由来の電源との組み合わせであってもよい。
電解装置70において、陰極2cの少なくとも一部が、隔膜4の非被覆上端4tよりも鉛直方向D1上方に存在することが好ましい。これにより、停止工程において、図7、図8に示すように、陽極室5a及び/又は陰極室5cの電解液の喫水線L(液面の位置31)を隔膜4の非被覆上端4tよりも鉛直方向上方に位置させつつ、陰極2cの少なくとも一部を、陰極室5c中に存在させ得る水素ガス層に露出させることができる。その結果、電気分解停止時における、隔膜を介した各電極室5a、5c間の気体の拡散・混合を抑制するとともに、さらに、陰極2cの劣化を抑制することができる。
隔膜4を介した気体の拡散・混合の抑制について、具体的には、従来の電解装置を用いた運転方法では、停止工程において、隔膜4の両方の表面が気体中に露出すると、それぞれの電極室5a、5c中の気体がわずかに隔膜4を透過してそれぞれの電極室5a、5cに拡散することがあった。しかし、停止工程において、陽極室及び/又は陰極室内の電解液の液面が隔膜の非被覆上端よりも鉛直方向上方に位置する運転方法では、停止工程において、陰極2cの一部を水素ガスに露出させながら、陽極室5a及び/又は陰極室5cの電解液の喫水線L(液面の位置)を隔膜4の非被覆上端4tよりも鉛直方向上方に位置させると、隔膜4の少なくとも一方の表面を液体に浸漬した状態にすることができる。したがって、各電極室5a、5c間の気体の拡散・混合を抑制することができる。
陰極2cの劣化の抑制について、具体的には、従来の電解装置の運転方法では、通電工程時に陰極(及び陽極2a)に蓄積された電荷により停止工程時に陰極2cに逆電流が生じ、当該逆電流が生じる際には、陰極自体を酸化させることがあった(通電工程時は、陰極室では還元反応が生じる)。そして、通電工程と停止工程が繰り返し行われることで陰極2cが劣化する懸念があった。これに対して、この電解装置70を用いた運転方法では、停止工程において、陰極2cが、図7、図8に示すように、そのうちの一部が喫水線Lよりも上方にあり水素ガスに露出するので、陰極2cの逆電流が生じても、陰極2cに接触する当該水素が酸化し、陰極2c自体の酸化を低減させて、陰極2cの劣化を抑制することができる。
なお、上記の「隔膜の非被覆上端」とは、隔膜4の鉛直方向D1の上端であるか、或いは、隔膜自体のうちの鉛直方向D1の上端側の部分が、例えば、図7(a)に示すように、隔膜4を電解槽50の外枠3の間に固定する際に用いるガスケット等で隔膜4の表面の一部が覆われている場合や、図8に示すように、ガスケット7とともに後述するように被覆材41で隔膜4の表面の一部が覆われている場合には、「隔膜の非被覆上端」とは、隔膜4のうちのガスケット7や被覆材41等で覆われていない部分についての鉛直方向D1の上端を指す。
なお、電解装置70としては、陰極2cが陰極本体部2c1から離間した陰極補助部2c2を有するものではなく、陰極2cが陰極本体部2c1のみからなり、陰極本体部2c1の鉛直方向D1の上端を、図7(a)の陰極補助部2c2の鉛直方向D1の上端の位置まで伸長させたものを用いることもできる。しかし、図7(a)のように陰極2cが陰極補助部2c2を有することにより、有しないものと比較して、メンテナンス時に陰極2cの交換をより行いやすくすることができる。また、陰極補助部2c2を用いることで陰極2c全体としての大きさを小さくすることができたり、或いは、例えば陰極補助部2c2は通電工程時の電解性能を陰極本体部2c2よりも低くする(例えば触媒量を減少させる等)ことができるので、陰極2cのコストを低減することができる。
また、陰極補助部2c2は、陰極本体部2c1に用い得る材料で形成することができ、また、陰極本体部2c1と同じ材料とすることもできるが、逆電流が生じた際に水素と接触して酸化させることができれば特に限定されない。また、陰極補助部2c2は、図7(b)の陰極室5cの模式的な平面図に示すように、鉛直方向D1の長さ、及び、鉛直方向D1に直交する方向の長さが、陰極本体部2c1の水平方向の長さ、及び、鉛直方向D1に直交する方向の長さよりも小さくなっている。具体的な寸法は、陰極補助部2c2が陰極本体部2c1とともに陰極室5cに収まる大きさよりも小さければ特に限定されず、陰極補助部2c2の鉛直方向D1の長さは、90mm以下が好ましい。
また、陰極本体部2c1と陰極補助部2c2と接続する導線部2c3は、陰極2cの基材に用い得る材料で形成することができ、また陰極本体部2c1と同じ材料とすることもできる。
なお、図7(a)の例では、図8の例で用いるような隔膜4の表面を覆う被覆材41を用いていないが、当該被覆材41を用いることもできる。
また、被覆材41は、図8では隔膜4の両方の表面に設けているが、隔膜4のうち被覆材41で覆われている部分が気体中に存在した場合に、隔膜4で区画されるそれぞれの電極室5a、5cの気体が透過するのを防止することができれば、隔膜4の片方の表面だけに設けてもよい。なお、このように、隔膜4の一方側・他方側の表面で非被覆上端の鉛直方向の位置が異なり、それによって一方側・他方側の表面で覆っている範囲が異なる場合には、鉛直方向下方側にある表面の非被覆上端を「隔膜の非被覆上端」とする。
本実施形態の使用方法としては、上述の本実施形態の電解システムを用いる方法が挙げられる。
例えば、電解槽への通電停止時に液面高さ制御手段を稼働させ、電解セル内の電解室中の電解液の液面高さを調整して用いる。
上記通電停止時とは、電解槽に供給される電流値が0Aの状態としてよいし、電解セル内の電解液の液面高さが鉛直下方向に低下する低い電流値での運転を含めてもよい。また、電解システム稼働時に電解液を循環させる送液ポンプ71も停止した状態としてよい。上記の電解システム及び使用方法は、電解槽に供給される電力(例えば電流)が停止し、電解液を循環させる送液ポンプも停止している状態において、上記トリガー等に応じて液面高さ制御手段30により、液面高さを調整することが好ましい。
アルカリ水電解である場合、電解液として、アルカリ塩が溶解したアルカリ性の水溶液を用いてよく、NaOH水溶液、KOH水溶液等を使用し、陰極で発生する水素ガスの製造、及び/又は陽極で発生する酸素ガスの製造に用いてよい。アルカリ塩の濃度としては、20質量%~50質量%が好ましく、25質量%~40質量%がより好ましい。
食塩電解である場合、電解液として、塩水、及びNaOHを使用し、陰極で発生する水素ガスの製造、及び/又は陽極で発生する塩素ガスの製造に用いてよい。
該運転方法によれば、電気分解停止時における、隔膜4を介した各電極室5a、5c間の気体の拡散・混合を一層抑制することが可能となる。
上記通電工程は、陽極室5a及び陰極室5c中の電解液の電気分解が行われる工程である。具体的には、図1に示すような電解装置70において、電解槽50の陽極室5a及び陰極室5cに電解液を送液ポンプ71を用いて送液しつつ、整流器74より正通電して陽極室5a及び陰極室5c中の電解液を電気分解する。また、電気分解より発生した酸素を含む電解液、水素を含む電解液を、それぞれ陽極室5a及び陰極室5cから気液分離タンク72へ送液し、それぞれ気液分離する。さらに、気液分離タンク72で気液分離した電解液は水補給器73にて水が補給されつつ、送液ポンプ71に戻る。このように通電工程において電解液が循環しながら電気分解されることにより、効率よく電気分解を行うことができる。
アルカリ塩の濃度としては、20質量%~50質量%が好ましく、25質量%~40質量%がより好ましい。
中でも、イオン導電率、動粘度、冷温化での凍結の観点から、25質量%~40質量%のKOH水溶液が特に好ましい。
上記温度範囲とすれば、高い電解効率を維持しながら、ガスケット7、隔膜4等の電解装置70の部材が熱により劣化することを効果的に抑制することができる。
電解液の温度は、85℃~125℃であることがさらに好ましく、90℃~115℃であることが特に好ましい。
特に、変動電源を使用する場合には、電流密度の上限を上記範囲にすることが好ましい。
なお、上記通電工程においては、上記の好ましい電流密度で電気分解を行うことが製造上好ましいが、当該好ましい電流密度を下回るような電流が流れる場合も通電工程に含まれる。
上記停止工程は、陽極室5a及び陰極室5c中の電解液の電気分解が停止している工程である。具体的には、上記通電工程では、陽極室5aにおいて電解液の電気分解により酸素が発生し、陰極室5cでは電解液の電気分解により水素が発生するが、当該停止工程では、このような電気分解が停止する。ただし、停止工程では、通電量が、電解装置70に流すことが許容される最大の正通電量(kA/m2)の1%以下となる通電量であれば正通電していてもよい。なお、最大の正通電量は、使用される電解装置70において運転条件として許容される最大の正通電量を意味する。
また、上記停止工程において、送液ポンプ71を停止させてもよく又は動かした状態にしてもよいが、好ましくは送液ポンプ71を停止することが好ましい。
具体的には、従来の電解装置の運転方法では、停止工程において、電解槽の電極室内には、電解運転時の電解液とともに、運転時に発生した気体が気体層として残ったままの状態となり、その結果として、電極室を陽極室及び陰極室に区画する隔膜の一部(両面)がそれぞれの電極室に存在する気体層に露出することがあった。そして、隔膜4の両方の表面が気体中に露出すると、それぞれの電極室5中の気体がわずかに隔膜4を透過してそれぞれの電極室5に拡散することがあった。しかし、上記の運転方法では、上記のようにすることにより、隔膜4は少なくとも一方の表面が液体に浸漬した状態になる。したがって、隔膜4を介した各電極室5a、5c間の気体の拡散・混合を抑制することができ、それゆえに、例えば陽極室5a内の酸素中の水素濃度や陰極室5c内の水素中の酸素濃度が局部的に高まることを避けることができる。
なお、上記の「隔膜の非被覆上端」(電極室に露出している隔膜の上端)とは、隔膜4の鉛直方向D1の上端であるか、或いは、隔膜4自体のうちの鉛直方向D1の上端側の部分が、例えば、図7(a)に示すように、隔膜4を電解槽の外枠3の間に固定する際に用いるガスケット等で隔膜4の表面の一部が覆われている場合や、図8に示すように、ガスケット7とともに被覆材41で隔膜4の表面の一部が覆われている場合には、「隔膜の非被覆上端」とは、隔膜4のうちのガスケット7や被覆材41等で覆われていない部分についての鉛直方向D1の上端4tを指す。また、陽極室5a内の電解液の液面Lと陰極室5c内の電解液の液面L(液面31)とは、鉛直方向の位置が相互に同じでも異なっていてもよい。
具体的には、停止工程において、送液ポンプ71を連続的又は間欠的に稼働し、陽極室5a及び/又は陰極室5cの液面Lを隔膜4の非被覆上端4tよりも鉛直方向上方に位置させることができる。これにより、電極室5a、5c内の電解液により隔膜4の少なくとも一方の表面を浸漬させることができる。また、停止工程中に電極室5a、5c内の電解液が減少するのを防止し、又は減少しても補充することもできる。なお、停止工程において、送液ポンプ71を連続的に稼働することで、電解液を循環させ続けてもよい。
また、送液ポンプ71は、通電工程から停止工程に移行した後から連続的又は間欠的に稼働させたり、停止工程移行して一定時間経過後から連続的又は間欠的に稼働させたり、することができる。
また、電解装置70が送液ポンプ71として、陰極室5cへ送液するための陰極側送液ポンプ、陽極室5aへ送液するための陽極側送液ポンプを有する場合には、それぞれ別々に稼働させることができる。これにより、より効率的に酸素中の水素濃度や陰極室5c内の水素中の酸素濃度の上昇を抑制することができる。
これにより、停止工程中に電極室5a、5c内の電解液が減少しても、隔膜4の表面の少なくとも一方を浸漬状態にし続けることができる。
陰極2cの劣化の抑制について具体的には、停止工程において、陰極2cがそのうちの一部で水素ガスに露出するので、陰極2cの逆電流が生じても、陰極2cに接触する当該水素が酸化し、陰極2c自体の酸化を低減させて、陰極2cの劣化を抑制することができる。
具体的な、陰極室5cの外部より陰極室5cに水素ガスを供給して陰極室5cに水素ガス層を形成させる方法としては、陰極室5cの陰極電解液出口5coの鉛直方向D1の上端の位置を、陰極室5cの外枠3の内面の鉛直方向D1の上端の位置よりも鉛直方向D1下方に、且つ、陰極2cの鉛直方向D1の上端よりも鉛直方向D1下方に位置させた電解装置70を用い、停止工程において、陰極室5c又は陰極室5cよりも流通方向の上流側(例えば、陰極室5cの上流側の配管)に設けた水素供給口を介して水素ガスを注入し続けることで、陰極室5c内の鉛直方向D1上方に水素ガス層(水素溜まり)が形成され続けるようにすることができる。
なお、流通方向とは、電解装置70の通電工程等において、電解装置70内を電解液が流れる方向である。
また、上記の陰極室5cの外部より供給する水素ガスは、水素分離タンク72a後に水素を貯蔵する貯蔵タンクと上記の水素供給口を配管で連結して当該貯蔵タンクより注入することや、水素が充填された移動式ボンベを上記の水素供給口に接続して当該ボンベより注入することができる。
停止工程において上記のように遮断することにより、停止工程において、陰極2cに生じる逆電流を低減することができる。具体的には、電気回路の遮断器、断路器、開閉器、逆向きの電流を阻害するダイオードを用いて遮断することができる。
複数のエレメント60が相互に絶縁された状態にする方法とは、具体的には、エレメント60の外枠3間で絶縁された状態とすることが好ましく、具体的には、例えば、エレメント60間に配置するガスケット7の絶縁性を高める等により行うことができる。また、ここでの絶縁とは、エレメント60間で、絶縁抵抗が1MΩ以上であることが好ましい。又は、当該ガスケット7の表面を絶縁性の樹脂シート(例えばポリテトラフルオロエチレン等のフッ素樹脂等)で覆うことにより行うことができる。
当該陰極2cの保有電荷量は、通電工程における電解液の電気分解を停止したとき(通電工程の終了時)に、当該保有電荷量(C)に基づき水素ガスの量を制御する陰極室5cの陰極2cが保有する電荷量である。具体的には、陰極2cの保有電荷量(C)は、陰極2cに正通電を流して十分に還元した後、正通電を停止し、逆電流を流しながら陰極2cの電位を測定して、陰極2cの電位が陽極2aの電位と等しくなるまでの逆電流の時間積算値を陰極2cが保有する保有電荷量とする。また、陽極2aの保有電荷量(c)は陰極2cの保有電荷量と同様に測定することができる。
また、上記の運転方法において、陰極2cの保有電荷量を、陽極2aの保有電荷量に対して0.1倍以下にする方法としては、陽極2aや陰極2cの材料等を適宜選択することにより行うことができる。
なお、隔膜露出(mm)は、隔膜の非被覆上端から液面までの鉛直方向長さを表す。
電極面積約3平米の大型電解セルを複数積層した大型電解槽50、及び電解液循環ポンプ71、熱交換器79を含むアルカリ水電解システムにおいて、通電停止から1時間ごとに電解液循環を実施するように液面高さ制御手段30に指令する。液面の時間変化グラフを図9に例示する。通電を停止すると、発熱源が無くなることから時間とともに電解液温度が低下し、電解液密度が増加する結果、液面が徐々に低下する。これに対し、1時間ごとに電解液循環を実施することで、液面が下限に至る前に液位を回復することができる。
なお、図9において、液位(即ち液面)の上限とは、電極室上端を表し、下限とは、非被覆上端4tから鉛直下方に50mmの位置である。
電極面積約3平米の大型電解セルを複数積層した大型電解槽50、及び電解液循環ポンプ71、熱交換器79を含むアルカリ水電解システムにおいて、通電停止時の電解液温度から5℃低下するごとに電解液循環を実施するように液面高さ制御手段30に指令する。電解液温度の時間経過グラフを図10に例示する。通電を停止すると、発熱源が無くなることから時間とともに電解液温度が低下し、電解液密度が増加する結果、液面が徐々に低下する。
これに対し、電解液温度が一定程度下がるごとに電解液循環を実施することで、液面が下限に至る前に液位を回復することができる。ただし、常時循環すると電解液中に溶存するガスによって、ガスの混合を促進するおそれがあるため、好ましくない。
電極面積約3平米の大型電解セルを複数積層した大型電解槽50、及び電解液循環ポンプ71、熱交換器79を含むアルカリ水電解システムにおいて、電解液循環停止中の各部圧力から、下式により陽極液頭圧La[kPa]、陰極液頭圧Lc[kPa]が求められる。
La=Pia―Poa
Lc=Pic―Poc
ここで、Pia:陽極電解液入口圧力[kPa]、Poa:酸素ガス圧力[kPa]、Pic:陰極電解液入口圧力[kPa]、Poc:水素ガス圧力[kPa]を示す。さらに、液頭圧を電解液密度および重力加速度で除することで、陽極液面高さHa[m]、陰極液面高さHc[m]を求めることができる。
Ha=La×1000/ρa・g
Hc=Lc×1000/ρc・g
ここで、ρa:陽極電解液密度[kg/m3]、ρc:陽極電解液密度[kg/m3]、g:重力加速度[m/s2]、を示す。ここで、一液循環方式であれば、ρa=ρcとみなすことができる。なお、電解液密度は一般的に温度依存性があるため、その補正を行う必要がある。
電解液停止中の圧力差からの演算により、HaあるいはHcが所定の値に達した場合、電解液循環を実施するように液面高さ制御手段30に指令することで、液面が下限に至る前に液位を回復することができる。
電極面積約3平米の大型電解セルを複数積層した大型電解槽50、及び電解液循環ポンプ71、熱交換器79を含むアルカリ水電解システムにおいて、通電および電解液循環停止中の電解槽の極間抵抗値を測定する手段を設けることで、電解槽内の平均液面高さを評価する。電解液は良導電体であり、他の経路の抵抗値は相対的に無視できることから、平均液面高さL[m]と電気抵抗値R[Ω]は次の関係にある。
1/R=a・L+b
L=a’/R+b’
ここで、a,b,a’,b’は係数である。Lが所定の値に達した場合、電解液循環を実施するように液面高さ制御手段30に指令することで、液面が下限に至る前に液位を回復することができる。
2 電極
2a 陽極
2c 陰極
2c1 陰極本体部
2c2 陰極補助部
2c3 導線部
2e 導電性弾性体
2r 集電体
3 外枠
4 隔膜
41 被覆材
4t 隔膜の非被覆上端
5 電極室
5a 陽極室
5c 陰極室
5i 電解液入口
5o 電解液出口
5ai 陽極電解液入口
5ao 陽極電解液出口
5ci 陰極電解液入口
5co 陰極電解液出口
6 整流版(リブ)
7 ガスケット
10 ヘッダー
10O 外部ヘッダー
10Oai 陽極入口ヘッダー(陽極入口側ホース)
10Oao 陽極出口ヘッダー(陽極出口側ホース)
10Oci 陰極入口ヘッダー(陰極入口側ホース)
10Oco 陰極出口ヘッダー(陰極出口側ホース)
20 導管
20Oai 陽極用配液管
20Oao、20ao 陽極用集液管
20Oci 陰極用配液管
20Oco、20co 陰極用集液管
30 液面高さ制御手段
31 液面
50 電解槽
51g ルーズヘッド
51h ファストヘッド
51i 絶縁板
51a 陽極ターミナルエレメント
51c 陰極ターミナルエレメント
51r タイロッド
51i 絶縁板
60 エレメント(複極式エレメント)
65 電解セル
70 水電解システム、電解装置
71 送液ポンプ
72a 陽極側気液分離タンク
72c 陰極側気液分離タンク
73 水補給器
74 整流器
77a 陽極液流量計
77c 陰極液流量計
78a 酸素ガス圧力計
78c 水素ガス圧力計
79 熱交換器
80a 酸素ガス圧力制御弁
80c 水素ガス圧力制御弁
81a 陽極液戻り配管
81c 陰極液戻り配管
82a 陽極電解液入口圧力計
82c 陰極電解液入口圧力計
D1 隔壁に沿う所与の方向(鉛直方向)
L 喫水線
Z ゼロギャップ構造
Claims (17)
- 隔膜を挟んで陽極と陰極とが重ねあわされた電解セルを含む電解槽、及び
前記電解槽への通電停止時に稼働する、前記電解セル内の電解液の液面高さを調整する液面高さ制御手段を含む、ことを特徴とする電解システム。 - 前記液面高さ制御手段が、前記液面高さを前記隔膜の非被覆上端より鉛直方向上方に制御する手段である、請求項1に記載の電解システム。
- 前記液面高さ制御手段が、電解液循環ポンプである、請求項1又は2に記載の電解システム。
- 前記液面高さ制御手段が稼働する時間が、通電停止の時間100%に対して、0%超20%以下である、請求項1~3のいずれか一項に記載の電解システム。
- 前記液面高さ制御手段が、通電停止時間に応じて液面高さを調整する、請求項1~4のいずれか一項に記載の電解システム。
- 前記液面高さ制御手段が、電解液温度に応じて液面高さを調整する、請求項1~5のいずれか一項に記載の電解システム。
- 前記液面高さ制御手段が、電解液の液頭圧に応じて液面高さを調整する、請求項1~6のいずれか一項に記載の電解システム。
- 前記液面高さ制御手段が、電気抵抗値に応じて液面高さを調整する、請求項1~7のいずれか一項に記載の電解システム。
- 前記液面高さ制御手段が、電解セル中の電解液の液面高さに応じて液面高さを調整する、請求項1~8のいずれか一項に記載の電解システム。
- 前記液面高さ制御手段が、電解液の前記液面高さが、前記隔膜の非被覆上端よりも鉛直方向下方に位置した場合に、送液ポンプにより電解液を電解セル内に注入する手段である、請求項9に記載の電解システム。
- アルカリ水電解用である、請求項1~10のいずれか一項に記載の電解システム。
- 請求項1~11のいずれか一項に記載の電解システムの使用方法。
- 相互に隔膜で区画された、陽極を有する陽極室と陰極を有する陰極室とを備える電解装置の運転方法であって、
前記陽極室及び前記陰極室中の電解液の電気分解が行われる通電工程と、
前記陽極室及び前記陰極室中の電解液の電気分解が停止している停止工程と、を有し、
前記停止工程において、前記陽極室及び/又は前記陰極室内の前記電解液の液面が前記隔膜の非被覆上端よりも鉛直方向上方に位置することを特徴とする、電解装置の運転方法。 - 前記停止工程において、前記陽極室及び前記陰極室内の前記電解液の液面を測定する液面計によりそれぞれの当該液面を監視し、当該陽極室及び当該陰極室内の当該液面が前記隔膜の非被覆上端よりも鉛直方向下方に位置した場合に、送液ポンプにより前記電解液を前記陽極室及び/又は前記陰極室内に注入し、前記陽極室及び/又は前記陰極室の液面を前記隔膜の非被覆上端よりも鉛直方向上方に位置させる、請求項13に記載の電解装置の運転方法。
- 前記停止工程において、送液ポンプを連続的又は間欠的に稼働し、前記陽極室及び/又は前記陰極室の液面を前記隔膜の非被覆上端よりも鉛直方向上方に位置させる、請求項13又は14に記載の電解装置の運転方法。
- 前記電解装置が、当該電解装置の電解槽よりも鉛直方向上方に位置する、前記電解液を貯留する貯留タンクを有し、
前記停止工程において、重力を利用して前記貯留タンク内の前記電解液を前記陽極室及び/又は前記陰極室に注入し、前記陽極室及び/又は前記陰極室の液面を前記隔膜の非被覆上端よりも鉛直方向上方に位置させる、請求項13~15のいずれか一項に記載の電解装置の運転方法。 - 前記陰極の少なくとも一部が、前記隔膜の非被覆上端よりも鉛直方向上方に存在する、請求項13~16のいずれか一項に記載の電解装置の運転方法。
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