EP4249642A1 - Procédé et agencement d'électrolyse - Google Patents

Procédé et agencement d'électrolyse Download PDF

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Publication number
EP4249642A1
EP4249642A1 EP22163339.9A EP22163339A EP4249642A1 EP 4249642 A1 EP4249642 A1 EP 4249642A1 EP 22163339 A EP22163339 A EP 22163339A EP 4249642 A1 EP4249642 A1 EP 4249642A1
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EP
European Patent Office
Prior art keywords
electrolysis
stack
cur
flow rate
electrolysis stack
Prior art date
Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
Pending
Application number
EP22163339.9A
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German (de)
English (en)
Inventor
Nga Thi Quynh DO
Vinh Phuc Bui Nguyen
Current Assignee (The listed assignees may be inaccurate. Google has not performed a legal analysis and makes no representation or warranty as to the accuracy of the list.)
Air Liquide SA
LAir Liquide SA pour lEtude et lExploitation des Procedes Georges Claude
Original Assignee
Air Liquide SA
LAir Liquide SA pour lEtude et lExploitation des Procedes Georges Claude
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Publication date
Application filed by Air Liquide SA, LAir Liquide SA pour lEtude et lExploitation des Procedes Georges Claude filed Critical Air Liquide SA
Priority to EP22163339.9A priority Critical patent/EP4249642A1/fr
Publication of EP4249642A1 publication Critical patent/EP4249642A1/fr
Pending legal-status Critical Current

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    • CCHEMISTRY; METALLURGY
    • C25ELECTROLYTIC OR ELECTROPHORETIC PROCESSES; APPARATUS THEREFOR
    • C25BELECTROLYTIC OR ELECTROPHORETIC PROCESSES FOR THE PRODUCTION OF COMPOUNDS OR NON-METALS; APPARATUS THEREFOR
    • C25B15/00Operating or servicing cells
    • C25B15/02Process control or regulation
    • C25B15/021Process control or regulation of heating or cooling
    • CCHEMISTRY; METALLURGY
    • C25ELECTROLYTIC OR ELECTROPHORETIC PROCESSES; APPARATUS THEREFOR
    • C25BELECTROLYTIC OR ELECTROPHORETIC PROCESSES FOR THE PRODUCTION OF COMPOUNDS OR NON-METALS; APPARATUS THEREFOR
    • C25B15/00Operating or servicing cells
    • C25B15/02Process control or regulation
    • C25B15/023Measuring, analysing or testing during electrolytic production

Definitions

  • the invention is directed to a method for performing an electrolysis as well as to a respective arrangement.
  • Electrolysis is preferably performed using renewable energies.
  • renewable energies such as solar and wind power fluctuates.
  • the object of the invention is to improve the prior art so that the temperature of an electrolysis process can be controlled particularly quickly and accurately.
  • a method for performing an electrolysis with an electrolysis stack wherein an electrolysis medium is used for the electrolysis that is cooled by means of a cooling medium provided at a flow rate F, wherein the flow rate F of the cooling medium is set to a value depending on a current value I cur of a current density of the electrolysis stack and a current value V cur of a cell voltage of the electrolysis stack.
  • the electrolysis method can be used for electrolysis of any electrolysis medium.
  • the electrolysis medium is liquid, in particular water.
  • the electrolysis medium can be water only.
  • the electrolysis medium may be water that contains dissolved salts such as KOH for alkaline electrolysis or electrolysis using anion exchange membrane cells.
  • the electrolysis products are preferably gaseous. In the case of water, hydrogen and oxygen can be obtained as the electrolysis products.
  • the electrolysis method is intended to be used for an industrial scale electrolysis. For example, it is preferred that at least one of the electrolysis products is obtained at a rate of 250 to 1500 Nm 3 per hour per electrolysis stack. This applies, in particular, to the production of hydrogen in the case of water electrolysis.
  • the electrolysis is preferably performed in an automated way.
  • the electrolysis method is performed using an electrolysis stack. That is, it is possible that the electrolysis method can be performed with one or more electrolysis stacks. Preferably, the electrolysis stacks each have a maximum rated DC power consumption in the range of 1 to 20 MW, in particular in the range of 3 to 10 MW.
  • the described electrolysis method is preferably used for industrial scale electrolysis. In particular, this is to be understood in contrast to experimental setups on a laboratory scale.
  • the industrial scale can be quantified in terms of the maximum rated DC power consumption of the electrolysis stack(s).
  • the maximum rated DC power consumption is what is commonly used to describe electrolysis stacks. For example, a "5 MW electrolysis stack" has a maximum rated DC power consumption of 5 MW.
  • the electrolysis is performed with the electrolysis medium within the electrolysis stack.
  • the electrolysis medium can be supplied to the electrolysis stack continuously, for example via a feed installation.
  • the electrolysis medium can be circulated by means of the feed installation, in particular through the electrolysis stack and further elements such as a separator and/or a heat exchanger. That is, the electrolysis medium can enter the electrolysis stack, where the electrolysis is performed. Thereby, the electrolysis medium is converted into the electrolysis products.
  • the remaining electrolysis medium can be guided out of the electrolysis stack. This remaining electrolysis medium is mixed with the electrolysis products.
  • the electrolysis medium After having separated the electrolysis products from the electrolysis medium, for example within a separator, the electrolysis medium can be fed back to the electrolysis stack. To this end, the circle is closed. This is supposed to be understood such that there is a closed loop path, along which the electrolysis medium can flow, which involves the electrolysis stack. However, the electrolysis medium is continuously converted into the electrolysis products, such that there is a loss of electrolysis medium.
  • the feed installation preferably comprises an inlet, via which new electrolysis medium can be introduced into the circulation. That is, a certain amount of the electrolysis medium introduced into the circulation via the inlet can pass the electrolysis stack one or several times, until this particular amount of the electrolysis medium is converted into the electrolysis products.
  • the feed installation is configured as a single feed line.
  • the feed installation can comprise multiple independent feed lines.
  • the feed installation comprises one or more separators.
  • the feed installation can be part of a circuit, via which the electrolysis medium can be circulated.
  • the electrolysis medium together with an anode product of the electrolysis can be guided from the anode of the electrolysis stack to an anode separator, where the anode product can be separated from the electrolysis medium.
  • the electrolysis medium together with a cathode product of the electrolysis can be guided from the cathode of the electrolysis stack to a cathode separator, where the cathode product can be separated from the electrolysis medium.
  • the electrolysis medium can be guided back to the electrolysis stack via a feed line that, together with the separators, is part of the feed installation.
  • the feed installation is configured as a feed line that has two branches, one of which being connected to an anode space or anode spaces of the electrolysis stack and the other one being connected to a cathode space or cathode spaces of the electrolysis stack.
  • the feed installation comprises multiple feed line branches that merge into a single feed line. For example, a first of these branches can be connected to the anode separator and a second of these branches can be connected to the cathode separator. Downstream of where the branches merge the feed line can be connected to the electrolysis stack as a single line or as two branches.
  • the electrolysis is performed at a temperature in the range of 50 to 120°C, in particular of 90 °C.
  • this temperature can be controlled indirectly.
  • the cooling medium is provided.
  • the electrolysis medium is circulated through the electrolysis stack and a heat exchanger, wherein the electrolysis medium is cooled in the heat exchanger by means of a cooling medium provided to the heat exchanger at the flow rate F.
  • the described method is also applicable in case the electrolysis medium is provided in the electrolysis stack in a stationary manner. In that case the electrolysis medium can be cooled by the cooling medium within the electrolysis stack. The cooling medium is fed at a flow rate such that the heating caused by the electrolysis and the cooling caused by the cooling medium result in a desired temperature of the electrolysis medium within the electrolysis stack.
  • the electrolysis medium can be cooled by the cooling medium at any point upstream or within the electrolysis stack. This includes that the electrolysis medium can be cooled by the cooling medium at any point of the feed installation. It is sufficient that the electrolysis medium is cooled by the cooling medium at a point where the cooling impacts the electrolysis. That is, the cooling is performed prior or during the electrolysis.
  • the feed installation can have an anode feed and a cathode feed that are separate from each other. In that case, the electrolysis medium can be cooled by the cooling medium in the anode feed and/or in the cathode feed. That is, it is sufficient to cool only the electrolysis medium that is fed to the anodes or to cool only the electrolysis medium that is fed to the cathodes.
  • the feed installation can have a joint feed for both anodes and cathodes.
  • the method can be applied to a single electrolysis stack.
  • the method can be applied to multiple electrolysis stacks.
  • the electrolysis medium can be fed to the electrolysis stacks using separate feed installations for the electrolysis stacks or using a common feed installation for all electrolysis stacks.
  • each electrolysis stack can be treated like the single electrolysis stack described exemplarily herein.
  • the described method can be performed using parameters of one of the electrolysis stacks. To this end, this electrolysis stack is assumed to be representative of the other electrolysis stacks. Alternatively, the parameters of all the electrolysis stacks can be taken into account.
  • the common feed installation can have, for example, a single heat exchanger via which the electrolysis medium can be cooled prior to being fed to the electrolysis stacks.
  • the flow rate F of the cooling medium is the flow rate at which the cooling medium is supplied to this heat exchanger.
  • the electrolysis medium is preferably circulated through the electrolysis stack and a heat exchanger.
  • the electrolysis medium can be cooled within the heat exchanger. This occurs upstream of the electrolysis stack to the end that the electrolysis medium is guided from the heat exchanger back to the electrolysis stack.
  • the heat exchanger is integrated into a feed line that is part of the feed installation.
  • the heat exchanger is integrated into a feed line that extends from an anode separator and/or from a cathode separator to the electrolysis stack. That is, the heat exchanger is preferably arranged between the anode separator and/or the cathode separator on the one hand and the electrolysis stack on the other hand.
  • the heat exchanger is arranged within the anode separator and/or the cathode separator. There can be more than one heat exchanger. For example, separate feed lines for the anode and cathode can have a respective heat exchanger.
  • the cooling medium is provided to the heat exchanger at a flow rate F.
  • the flow rate F of the cooling medium has an influence on the temperature of the electrolysis medium.
  • the temperature of the electrolysis medium downstream of the heat exchanger can also depend on the temperature of the cooling medium and on the flow rate at which the electrolysis medium flows through the heat exchanger. The best results are thus obtained in the preferred case that the temperature of the cooling medium is constant and the electrolysis medium flows at a constant flow rate through the heat exchanger.
  • acceptable results can also be obtained if these conditions are not met.
  • a minor deviation in cooling medium temperature and/or in flow rate of the electrolysis medium will only have a minor influence on the result.
  • the temperature of the cooling medium does not fluctuate by more than 20 °C, in particular by not more than 10 °C, and/or that the electrolysis medium flows through the heat exchanger at a flow rate that does not fluctuate by more than 20 % of the average flow rate, in particular not by more than 10 % of the average flow rate. Even if these preferred conditions are not met, the described method can outperform prior art teachings.
  • the temperature of the electrolysis medium downstream of the heat exchanger in general depends on the temperature of the electrolysis medium upstream of the heat exchanger.
  • the temperature of electrolysis medium upstream of the heat exchanger results from the temperature of the electrolysis medium downstream of the heat exchanger and from the heating caused by the electrolysis.
  • This heating depends on the electrical energy supplied to the electrolysis stack.
  • this heating can be predicted from the current density of the electrolysis stack and the cell voltage of the electrolysis stack.
  • the flow rate F of the cooling medium is set to a value depending on a current value I cur of the current density of the electrolysis stack and a current value V cur of the cell voltage of the electrolysis stack.
  • the current value I cur of the current density of the electrolysis stack and the current value V cur of the cell voltage of the electrolysis stack can be determined by measurement. Alternatively, these values can be extracted from a control unit, which supplies electrical energy to the electrolysis stack at these values.
  • the current density is the electrical current applied to the electrolysis stack divided by the cell area of the electrolysis cells of the electrolysis sack.
  • the letter I is used to indicate the current density. It is also common to use the letter I for the current and the letter J for the current density. Instead of the current density, the current applied to the electrolysis stack could be used as well. This is because the cell area is a constant.
  • the cell voltage of the electrolysis stack is the voltage applied to each of the electrolysis cells of the electrolysis stack. For example, if the electrolysis cells of the electrolysis stack are electrically in series, the voltage applied to the electrolysis stack is the sum of the respective cell voltages applied to the electrolysis cells of the electrolysis stack. The cell voltage is preferably the same for all electrolysis cells.
  • the cell voltage can be obtained by dividing the voltage applied to the electrolysis stack by the number of electrolysis cells the electrolysis stack has. This can even be done in case the electrolysis cells of the electrolysis stack are not identical to each other. In that case, an average cell voltage is obtained. It is generally preferred to use the average cell voltage as the cell voltage in the described method.
  • the letter V is used for the cell voltage.
  • the described method is particularly fast. In particular, fluctuations in the supply of the electrical energy can be reacted to particularly quickly. To this end, the described method is particularly suitable to be used with renewable energies. It is thus preferred that electrical energy is supplied to the electrolysis stack from a renewable energy source.
  • the renewable energy source can be a solar power plant or a wind turbine.
  • the described method is also applicable with any other energy source.
  • the quick response according to the invention can be achieved in that the current density and the cell voltage of the electrolysis stack are used for the temperature control.
  • a change in the supply of the electrical energy is expressed in that the current density and the cell voltage of the electrolysis stack change. To this end, the change in the supply of the electrical energy can be detected as such and the flow rate of the cooling medium can be adapted accordingly.
  • the temperature control was based on a temperature measurement, a change in the supply of the electrical energy could only be detected once the measured temperature changes. However, the temperature changes in such a case only with a delay. To this end, the temperature of the electrolysis process can be controlled with the described method particularly quickly. This results in a particularly accurate control.
  • the flow rate F is set using a feedforward control process.
  • the flow rate of the cooling medium was controlled based on a measurement of the temperature, this could be referred to as a feedback control process. This is because the result (i.e. the temperature) is observed and fed back to where a manipulation is possible (i.e. the cooling using a cooling medium at a certain flow rate).
  • the described method constitutes a feedforward control process.
  • the cause for a potential change i.e. the supply of electrical energy that potentially could change the temperature
  • a manipulation i.e. in the cooling using a cooling medium at a certain flow rate
  • a reference value F ref of the flow rate of the cooling medium is provided.
  • the reference conditions are defined, in particular, in that therein the current density of the electrolysis stack has a reference value I ref and the cell voltage of the electrolysis stack has a reference value V ref .
  • Step a) can be considered a calibration step.
  • the reference conditions can be chosen arbitrarily.
  • the reference conditions can be set to the current conditions at the time step a) is supposed to be carried out. That is, in order to perform step a), the current value I cur of the current density of the electrolysis stack and the current value V cur of the cell voltage of the electrolysis stack can be determined, for example by measurement or by reading from a control unit, and the reference value I ref of the current density of the electrolysis stack and the reference value V ref of the cell voltage of the electrolysis stack can be defined to be equal to these values.
  • the reference value F ref of the flow rate of the cooling medium can be provided in that it is determined which flow rate is desired under the reference conditions. This can be done experimentally. Therein, the reference value F ref can be set to a value that provides a satisfactory result.
  • the reference values F ref , I ref and V ref can be determined theoretically.
  • the reference values I ref and V ref can be set to a arbitrary values and it can be calculated which flow rate of the cooling medium would be desired for these values.
  • the reference values F ref , I ref and V ref can be determined prior to the beginning of the described method.
  • the current value I cur of the current density of the electrolysis stack and the current value V cur of the cell voltage of the electrolysis stack deviate as little as possible from the respective reference values I ref and V ref .
  • the reference value I ref of the current density of the electrolysis stack and the reference value V ref of the cell voltage of the electrolysis stack are defined to be respective average values of the current value I cur of the current density of the electrolysis stack and the current value V cur of the cell voltage of the electrolysis stack, respectively, taken over a period of time.
  • the period of time is preferably, at least an hour, in particular at least a day or even at least a week.
  • step b) the current value I cur of the current density of the electrolysis stack and the current value V cur of the cell voltage of the electrolysis stack are determined. This can be done by measurement or by reading from a control unit. Also, this can be done in that the respective values are calculated from other parameters that are measured or read from the control unit. It is sufficient that after step b) a value representing the current value I cur of the current density of the electrolysis stack and a value representing the current value V cur of the cell voltage of the electrolysis stack are known. For example, instead of the actual current value I cur of the current density of the electrolysis stack and the actual current value V cur of the cell voltage of the electrolysis, electrical signals could be used that represent the respective value.
  • step c) the flow rate F of the cooling medium is set. This means that the actual flow rate of the cooling medium is affected, which results in a respective cooling effect on the electrolysis medium.
  • the flow rate F is set to a value that depends on the reference values F ref , I ref and V ref as well as on the current values I cur and V cur .
  • the current values I cur and V cur can be compared with the respective reference value I ref and V ref . If there is no deviation, the flow rate F can be simply set to the reference value F ref . If there is a deviation, the flow rate F can be set to a value that deviates from the reference value F ref accordingly.
  • the value to which the flow rate F of the cooling medium is set in step c) further depends on
  • thermoneutral cell voltage V th is the voltage drop across each of the electrolysis cells of the electrolysis stack that is sufficient not only to drive the electrolysis reaction, but to also provide heat so as to maintain a constant temperature. It was found that taking the thermoneutral cell voltage V th into account can improve the accuracy of the described method.
  • the value to which the flow rate F of the cooling medium is set further depends on a feedback correction ⁇ F FB .
  • the flow rate F of the cooling medium can be set to a value that is the sum of the feedback correction ⁇ F FB and a contribution depending on the current value I cur of the current density of the electrolysis stack and the current value V cur of the cell voltage of the electrolysis stack.
  • the latter can be referred to as a feedforward value F FF .
  • F F FF I cur V cur + ⁇ F FB .
  • F FF ( I cur , V cur ) indicates that F FF depends on I cur and V cur .
  • a feedback correction ⁇ F FB can be taken into account in any other embodiment as well.
  • the feedback correction ⁇ F FB is initially set to be equal to zero.
  • the flow rate F is than set to F FF ( I cur , V cur ).
  • F FF I cur , V cur
  • By measuring the temperature it can be checked whether or not the result obtained thereby is satisfying, for example by comparing the measured temperature with a temperature set point. In case the measured temperature equals the temperature set point, ⁇ F FB remains zero. If the supply of electrical energy changes suddenly, for example in the case of a renewable energy source, this can be compensated for because F FF ( I cur , V cur ) changes immediately. Ideally, this compensation is as accurate as that the temperature remains at the set point so that ⁇ F FB remains zero.
  • the current value I cur of the current density of the electrolysis stack is determined by measurement and/or the current value V cur of the cell voltage of the electrolysis stack is determined by measurement.
  • an arrangement for performing an electrolysis that comprises:
  • the advantages and features of the method are transferrable to the arrangement, and vice versa.
  • the method is preferably performed using the arrangement.
  • the cooling installation can be configured for providing the cooling medium for the electrolysis in that the cooling installation is configured for providing the cooling medium to a heat exchanger of a feed installation, wherein the heat exchanger is arranged upstream of the electrolysis stack.
  • the cooling installation can be configured for providing the cooling medium to the electrolysis stack.
  • Fig. 1 shows an arrangement 2 with an electrolysis stack 1 configured for the electrolysis of water.
  • the electrolysis stack 1 is connected to a feed installation 11, via which water can be fed to the electrolysis stack 1 as an electrolysis medium.
  • the feed installation 11 is realized as a single feed that provides the water to both an anode and a cathode space of the electrolysis stack 1.
  • an electrolysis can be performed with the water.
  • the water remaining in the anode space can be guided together with the anode product, i.e. oxygen, from the electrolysis stack 1 to an anode separator 5.
  • the gaseous oxygen can be extracted via an oxygen outlet 8 and the liquid water can be fed back to the electrolysis stack 1.
  • new water can be introduced into the anode separator 5 via a water feed 7. That is, the feed installation 11 comprises the anode separator 5, the water feed 7 and the conduit from the electrolysis stack 1 to the anode separator 5 as well as the conduit from the anode separator 5 back to the electrolysis stack 1.
  • the water remaining in the cathode space can be guided together with the cathode product, i.e. hydrogen, from the electrolysis stack 1 to a cathode separator 6.
  • the cathode separator 6 From the cathode separator 6 the gaseous hydrogen can be extracted via a hydrogen outlet 9 and the liquid water can be extracted via a water outlet 12.
  • a heat exchanger 10 is provided that is connected to a cooling installation 3.
  • the cooling installation 3 is configured for providing a cooling medium for the electrolysis at a flow rate F.
  • the water coming from the electrolysis stack 1 is cooled before it is fed back, via the anode separator 5, to the electrolysis stack 1. Since the water is circled back to the electrolysis stack 1, the water is cooled before being used in the electrolysis (again).
  • the arrangement comprises a control unit that is electrically connected to the electrolysis stack 1 and to the cooling installation 3.
  • the control unit is configured for controlling the arrangement 2 so as to perform an electrolysis using a method, in which the water used for the electrolysis is cooled by means of the cooling medium provided at a flow rate F, wherein the flow rate F of the cooling medium is set to a value depending on a current value I cur of a current density of the electrolysis stack 1 and a current value V cur of a cell voltage of the electrolysis stack 1.
  • the feedforward term is obtained in a feedforward control installation 4, which is part of the control unit. Therefore, the feedforward control installation 4 can receive the values I cur and V cur from the electrolysis stack 1 as indicated by two dotted lines.
  • the further parameters of the feedforward term F FF can be stored in a storage of the feedforward control installation 4.
  • the feedback correction ⁇ F FB can be obtained with a temperature controller TC, which is also part of the control unit.
  • Fig. 2a to 2c show data simulated for a conventional electrolysis arrangement (which is not shown in the figures).
  • the conventional electrolysis arrangement has a single electrolysis stack with a heat exchanger and common separators that are placed horizontally. The temperature is controlled by means of a conventional PID control.
  • Fig. 2a illustrates the current density applied to the electrolysis stack of the conventional electrolysis arrangement over the time. It can be seen that a jump in the current density occurs shortly before 200 s. This is supposed to simulate a sudden change in the supply of electric energy to the electrolysis stack, for example in case a renewable energy source is used.
  • Fig. 2b and 2c show simulated data that illustrate how the conventional electrolysis arrangement reacts to the jump in the current density shown in Fig. 2a .
  • the temperature is shown over the time.
  • Fig. 2b refers to the start of operation and Fig. 2c to a later stage, where the electrolysis stack has degraded by 20 %. It can be seen that the jump in the current density results in a jump in the temperature by about 9 °C ( Fig. 2b ) and 13 °C ( Fig. 2c ), respectively.
  • Fig. 3a to 3c show data simulated for the arrangement 2 of Fig. 1 . As can be seen from Fig. 3a , the same jump in the current density is simulated.
  • Fig. 3b and 3c show simulated data that illustrate how the arrangement 2 of Fig. 1 reacts to the jump in the current density.
  • the temperature is shown over the time similar to Fig. 2b and 2c.
  • Fig. 3b refers to the start of operation and Fig. 3c to a later stage, where the electrolysis stack has degraded by 20 %. It can be seen that the jump in the current density results in a jump in the temperature by about 3.5 °C ( Fig. 3b) and 2 °C ( Fig. 3c ), respectively.
  • the arrangement 2 of Fig. 1 addressed in Fig. 3a to 3c outperforms the conventional arrangement addressed in Fig. 2a to 2c .
  • Fig. 3a to 3c refer to a case with feedback correction ⁇ F FB the same results could be obtained for various situations without feedback correction ⁇ F FB , for example in case external conditions remain unchanged. This is particularly true because the effect of the feedback correction ⁇ F FB is comparatively slow.

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  • Chemical & Material Sciences (AREA)
  • Engineering & Computer Science (AREA)
  • Automation & Control Theory (AREA)
  • Chemical Kinetics & Catalysis (AREA)
  • Electrochemistry (AREA)
  • Materials Engineering (AREA)
  • Metallurgy (AREA)
  • Organic Chemistry (AREA)
  • Analytical Chemistry (AREA)
  • Electrolytic Production Of Non-Metals, Compounds, Apparatuses Therefor (AREA)
EP22163339.9A 2022-03-21 2022-03-21 Procédé et agencement d'électrolyse Pending EP4249642A1 (fr)

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EP22163339.9A EP4249642A1 (fr) 2022-03-21 2022-03-21 Procédé et agencement d'électrolyse

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EP22163339.9A EP4249642A1 (fr) 2022-03-21 2022-03-21 Procédé et agencement d'électrolyse

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Citations (3)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US20040131902A1 (en) * 2002-11-27 2004-07-08 Hydrogenics Corporation Regenerative power supply system and components thereof
EP3476978A1 (fr) * 2016-06-24 2019-05-01 Toagosei Co., Ltd. Appareil de production d'hydroxyde alcalin et procédé pour faire fonctionner un appareil de production d'hydroxyde alcalin
CN113279002A (zh) * 2021-04-29 2021-08-20 全球能源互联网研究院有限公司 多槽并联电解制氢的控制方法及系统

Patent Citations (3)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US20040131902A1 (en) * 2002-11-27 2004-07-08 Hydrogenics Corporation Regenerative power supply system and components thereof
EP3476978A1 (fr) * 2016-06-24 2019-05-01 Toagosei Co., Ltd. Appareil de production d'hydroxyde alcalin et procédé pour faire fonctionner un appareil de production d'hydroxyde alcalin
CN113279002A (zh) * 2021-04-29 2021-08-20 全球能源互联网研究院有限公司 多槽并联电解制氢的控制方法及系统

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