FR3115796A1 - High temperature electrolyser system optimized by coupling to a heat pump - Google Patents

Abstract

High temperature electrolyser system optimized by coupling to a heat pump The invention relates to a system comprising - a high temperature (EHT) electrolyser (1), - a first supply line (2) of the electrolyser (1 ) into steam, - a first evacuation line (4) of the dihydrogen from the electrolyser (1), - a second evacuation line (3) of the dioxygen from the electrolyser (1), - a first heat exchange module (5) configured to ensure heat exchange between the first steam supply line (2) and the first dihydrogen evacuation line (4), - a steam generator (6) arranged on the first steam supply line (2), upstream of the first heat exchange module (5), and configured to produce steam from liquid water, characterized in that that the system comprises a module for recovering the thermal energy of the dihydrogen at the output of the heat exchange module (5) for the benefit of the first st steam supply line (2), the recovery module comprising a heat pump comprising a fluidic circuit (27) configured to receive a heat transfer fluid, a first evaporator (25a) arranged on the first evacuation (2) downstream of the first heat exchange module (5) configured to transfer thermal energy from the dihydrogen to the heat transfer fluid, a compressor (26), a condenser (23) arranged on the first supply line (2 ) in steam upstream of the steam generator (6) and configured to transfer thermal energy from the heat transfer fluid to liquid water, an expansion valve (24). The present invention relates to the field of solid oxide high temperature water electrolysis (SOEC, English acronym for " Solid Oxide Electrolyte Cell ") and that of solid oxide fuel cells (SOFC, English acronym for " Solid Oxide Fuel Cell"). It finds application particularly in optimizing the energy consumption of a SOEC electrolyser system. Figure for abstract: Fig.1

Description

High temperature electrolyser system optimized by coupling to a heat pump

The present invention relates to the field of solid oxide fuel cells (SOFC, acronym for "Solid Oxide Fuel Cell") and that of high temperature water electrolysis (EHT, or EVHT for electrolysis of steam). high temperature water, or HTE acronym for High Temperature Electrolysis, or HTSE acronym for High Temperature Steam Electrolysis), also solid oxide (SOEC, acronym for " Solid Oxide Electrolyte Cell "). It finds application particularly in optimizing the energy consumption of a SOEC electrolyser system.

STATE OF THE ART

The electrolysis of water is an electrolytic reaction which decomposes water into dioxygen and dihydrogen gas with the help of an electric current according to the reaction: H ₂ O --> H ₂ + 1/2 O ₂ .

To carry out the electrolysis of water, it is advantageous to carry it out at high temperature, typically between 600 and 950°C, because part of the energy necessary for the reaction can be provided by heat, which is less expensive than Electricity and reaction activation are more efficient at high temperatures and do not require a catalyst. A solid oxide electrolysis cell or "SOEC" (Anglo-Saxon acronym "Solid Oxide Electrolyte Cell") comprises in particular: - a first porous conductive electrode, or "cathode", intended to be supplied with steam for the production of dihydrogen, - a second porous conductive electrode, or "anode", through which escapes the dioxygen produced by the electrolysis of water injected on the cathode, and - a solid oxide membrane (dense electrolyte) taken into sandwiched between the cathode and the anode, the membrane being anionic conductor for high temperatures, usually temperatures above 600°C. By heating the cell to at least this temperature and by injecting an electric current I between the cathode and the anode, there is then a reduction of water on the cathode, which generates dihydrogen (H2) at the level of the cathode and oxygen at the anode. To implement electrolysis at high temperature, it is known to use an electrolyser of the SOEC type consisting of a stack of elementary units each comprising a solid oxide electrolysis cell, consisting of three anode/electrolyte/cathode layers. superposed one on the other, and interconnection plates in metal alloys also called bipolar plates, or interconnectors. The function of the interconnectors is to ensure both the passage of electric current and the circulation of gases in the vicinity of each cell (water vapor injected, hydrogen and oxygen extracted in an EHT electrolyser; air and hydrogen injected and water extracted in a SOFC cell) and to separate the anode and cathode compartments which are the gas circulation compartments on the side respectively of the anodes and the cathodes of the cells.

To carry out the electrolysis of water vapor at high temperature EHT, water vapor H2O is injected into the cathode compartment.

Under the effect of the current applied to the cell, the dissociation of water molecules in vapor form is carried out at the interface between the hydrogen electrode (cathode) and the electrolyte: this dissociation produces dihydrogen gas H2 and oxygen ions. The dihydrogen is collected and evacuated at the outlet of the hydrogen compartment. The oxygen ions migrate through the electrolyte and recombine into dioxygen O ₂ at the interface between the electrolyte and the oxygen electrode (anode).

For the effective implementation of the electrolysis by the stack, the stack is brought to a temperature above 600°C, usually a temperature between 600°C and 950°C, the gas supply is switched on running at a constant rate and an electrical power source is connected between two terminals of the stack in order to cause the current I to flow there.

The efficiency of the transformation of electricity into hydrogen is a key point in order to ensure the competitiveness of the technology. Electricity consumption mainly takes place during the electrolysis reaction itself, but almost 30% of the electrolyser's consumption comes from the thermal/hydraulic fluid management system. That is to say the architecture external to the electrolyser and the management of fluids and thermal energy in this architecture.

The evaporation of the water used in the electrolyser is the most important energy consumption of this thermal/hydraulic management system. Conventionally, this function is provided by an electric steam generator which consumes 20% of the overall consumption of the electrolyser.

Moreover, in general, a significant part of the energy is released into the surrounding environment. For example, during the hydrogen drying and compression phase, it is necessary to greatly cool this mixture in order to allow the condensation of the water present in the water/hydrogen mixture. This condensation takes place for the most part at a temperature below the evaporation temperature of the water entering the electrolyser, which means that a very small part of this condensation energy is usable.

There is therefore a need to minimize this consumption by optimizing the architecture and fluid management of the electrolyser system.

An object of the present invention is therefore to provide a high temperature electrolyser system optimized by coupling with a heat pump.

The other objects, features and advantages of the present invention will become apparent from a review of the following description and the accompanying drawings. It is understood that other benefits may be incorporated.

SUMMARY

To achieve this objective, according to one embodiment the invention provides a system comprising: - a high temperature electrolyser (EHT), - a first supply line of the electrolyser configured to supply the electrolyser with steam , - a first discharge line of the electrolyser configured to discharge dihydrogen from the electrolyser, - a second discharge line from the electrolyser configured to discharge from the electrolyser dioxygen, - a first exchange module configured to ensure heat exchange between the first steam supply line and the first dihydrogen evacuation line, - a steam generator arranged on the first steam supply line, upstream of the first heat exchange module, and configured to produce water vapor from liquid water, characterized in that the system comprises a module for recovering the thermal energy of the hydrogen output e of the first heat exchange module for the benefit of the first steam supply line, the recovery module comprising a heat pump comprising: - a fluidic circuit configured to receive a heat transfer fluid, - a first evaporator arranged on the first evacuation line downstream of the first heat exchange module configured to transfer thermal energy from the dihydrogen to the heat transfer fluid, - a compressor configured to compress the heat transfer fluid, - a condenser arranged on the first supply line in steam upstream of the steam generator and configured to transfer thermal energy from the heat transfer fluid to liquid water, - an expansion valve configured to expand the heat transfer fluid, - the fluidic circuit being configured to fluidically connect the first evaporator to the compressor, the compressor to the condenser, the condenser to the expansion valve and the expansion valve to the first evaporator.

This arrangement makes it possible to recover the thermal energy of the dihydrogen produced by the electrolyser to participate in the evaporation of liquid water and therefore reduce the energy consumption of the system while taking into account the constraints of the components to allow the use of classic components.

Thus, the system uses the heat of the dihydrogen at the output of the electrolyser, but after the first heat exchange module so that the thermal rejection of the dihydrogen in the evaporator is exploited at a lower temperature via an active system of a heat pump. The calories recovered from the dihydrogen are reinjected at a temperature above the evaporation temperature of the water upstream of the liquid water steam generator.

The heat pump thus arranged makes it possible to operate with an interesting efficiency due to the low temperature difference between the evaporation temperature of the water in the steam generator and the temperature of the hydrogen flow in the first evaporator.

BRIEF DESCRIPTION OF FIGURES

The aims, objects, as well as the characteristics and advantages of the invention will emerge better from the detailed description of an embodiment of the latter which is illustrated by the following accompanying drawings in which:

There is a functional diagram representing the system according to the invention.

There represents a functional diagram representing the fluidic circuit of the heat pump.

The drawings are given by way of examples and do not limit the invention. They constitute schematic representations of principle intended to facilitate understanding of the invention and are not necessarily scaled to practical applications.

DETAILED DESCRIPTION

Before starting a detailed review of embodiments of the invention, optional characteristics are set out below which may possibly be used in combination or alternatively:

According to one example, the heat pump comprises a second evaporator, optimizing the recovery of the waste heat from the dihydrogen.

According to one example, the second evaporator is arranged in series on the fluidic circuit of the heat pump downstream of the first heat exchanger and preferably upstream of the compressor.

According to one example, the system comprises at least a first air cooler or a second heat exchanger arranged on the first dihydrogen evacuation line, downstream of the first evaporator.

According to one example, the system comprises at least a second air cooler or a third heat exchanger arranged on the first dihydrogen evacuation line, downstream of the second evaporator.

According to one example, the system comprises downstream of the first air cooler and upstream of the second evaporator a liquid/gas separator.

According to one example, the system comprises a first heat exchanger arranged between the second dioxygen evacuation line and the first steam supply line, upstream of the condenser, so as to transmit the thermal energy of the dioxygen to liquid water upstream of the condenser.

Thus, this heat exchanger participates in raising the temperature of the liquid water before the steam generator so as to limit its energy consumption thanks to the recovery of the heat from the oxygen produced by the electrolyser.

According to one example, the system comprises a second electrolyser supply line configured to supply the electrolyser with air or a gas containing oxygen.

According to one example, the system comprises a second heat exchange module configured to provide heat exchange between the second air supply line and the second oxygen evacuation line.

Thus, the second heat exchange module makes it possible to heat the incoming flow of air by the heat of the outgoing flow of oxygen.

According to one example, the second heat exchanger is arranged between the first dihydrogen evacuation line, downstream of the first evaporator, and the second air supply line.

Thus, the heat exchanger arranged between the second air supply line and the first dihydrogen evacuation line makes it possible to use the residual heat of the dihydrogen to heat the incoming air destined for the electrolyser. The exchanger advantageously replaces a dry cooler which eliminates the consumption of the dry cooler fan, which consumes a lot of energy.

According to one example, the system comprises a compressor arranged on the second air supply line and intended to compress the air, preferably arranged upstream of the second heat exchange module and preferably downstream of the second heat exchanger replacing the air cooler .

The upstream and downstream, the entry, the exit, at a given point are taken in reference to the direction of circulation of the fluid.

A parameter "substantially equal/greater/less than" a given value means that this parameter is equal/greater/less than the given value, to within plus or minus 10%, or even within plus or minus 5%, of this value

The system according to the invention comprises a high temperature electrolyser 1 (EHT). Preferably, the electrolyser 1 is of the SOEC type, the English acronym for “ Solid Oxide Electrolyte Cell ”, that is to say with solid oxide.

The system comprises several supply and evacuation lines connected to the electrolyser 1. Thus, by line is meant a pipe, a tube or a set of pipes or tubes which allow the transport of fluid to and from the electrolyser 1 .

The system according to the invention comprises a first supply line 2 of the electrolyser 1 capable of supplying the electrolyser 1 with steam. According to one possibility, the first supply line 2 is configured to supply the electrolyser 1 with steam, by which is meant that the first supply line 2 can supply a mixture of steam and other gas(es), for example air or dihydrogen or carbon dioxide. Upstream in this first supply line 2, water vapor has not yet formed and the first supply line 2 is configured to receive liquid water. According to a preferred possibility, the first supply line 2 comprises a first portion receiving liquid water and a second portion receiving steam. Preferably, the first portion is located upstream of a steam generator 6 and the second portion is located downstream of said steam generator 6.

The system according to the invention comprises a first evacuation line 4 able to evacuate dihydrogen (H ₂ ) from the electrolyser 1 . Preferably, the first evacuation line 4 receives the dihydrogen. The dihydrogen is advantageously produced by the electrolyser 1. The dihydrogen is in gaseous form. The first evacuation line 4 can evacuate a mixture of dihydrogen and water vapour, called residual which has not been decomposed by the electrolyser 1.

The system according to the invention comprises a second evacuation line 3 able to evacuate dioxygen (O ₂ ) from the electrolyser 1 . Preferably, the second evacuation line 3 receives the oxygen. The oxygen is advantageously produced by the electrolyser 1. The oxygen is in gaseous form. The second evacuation line 3 evacuates according to one possibility a gas enriched in oxygen, for example air enriched in oxygen.

In the rest of the description, the first supply line 2 is called the first steam supply line 2, the first evacuation line 4 is called the first evacuation line 4 of dihydrogen and the second line of evacuation 3 is called second evacuation line 3 in dioxygen without being limiting on the gas, the fluid or the mixture which can be transported in these lines.

According to one possibility, the system comprises a first heat exchange module 5 configured to ensure a heat exchange between the first steam supply line 2 and the first evacuation line 4 for dihydrogen. This heat exchange module is configured to transfer the calories of the dihydrogen from the electrolyser 1 to the water intended to supply the electrolyser 1. A flow of dihydrogen gas ensures the increase in temperature of the water flow this while also making it possible to cool the flow of dihydrogen evacuated and which is advantageously dried and/or compressed with a view to its use.

The first heat exchange module 5 comprises according to one embodiment at least one heat exchanger 5a configured to ensure the heat transfer from dihydrogen to steam. According to a preferred embodiment, the first heat exchange module 5 comprises two heat exchangers 5a, 5b arranged in series between the first supply line 2 and the first discharge line 4. This arrangement makes it possible to provide a second heat exchanger 5b adapted to the temperature of the dihydrogen at the outlet of the electrolyser 1, conventionally of the order of 700° C., and a more usual first heat exchanger 5a adapted to the temperature of the dihydrogen after passing through a heat exchanger, that is conventionally of the order of 330°C. In this way, the components are optimized for the temperatures and heat transfers to be achieved.

The system according to the invention comprises a steam generator 6. The steam generator 6 is intended to produce steam from liquid water. The steam generator 6 is supplied with energy to ensure the increase in temperature of the liquid water above its evaporation temperature. The steam generator 6 is a component constituting the main energy consumption of an electrolyser system according to the state of the art. The steam generator 6 is arranged on the first steam supply line 2.

According to one aspect of the invention, the system comprises a dihydrogen thermal energy recovery module at the output of the heat exchange module 5 for the benefit of the first steam supply line 2.

According to one possibility, the recovery module comprises a heat pump arranged between the first evacuation line 4 of the dihydrogen and the first supply line 2 of steam. The heat pump is configured to transfer thermal energy from dihydrogen to liquid water.

The heat pump comprises a condenser 23, an expander 24, at least a first evaporator 25a, and a compressor 26. The heat pump comprises a fluidic circuit 27 able to receive a heat transfer fluid.

The heat transfer fluid is for example a fluid conventionally used in heat pumps such as 1234yf: 2,3,3,3-tetrafluoropropene (HFO-1234yf), or R245FA pentafluoropropane, or R290 propane

The fluidic circuit 27 ensures the fluidic connection of the components of the heat pump, preferably in a closed circuit.

According to one embodiment, the fluidic circuit 27 comprises a fluidic connection 200 connected between the outlet of the compressor 26 and the inlet of the condenser 23. Advantageously, the fluidic circuit 27 comprises a fluidic connection 201 connected between the outlet of the condenser 23 and the inlet of the expander 24. Advantageously, the fluid circuit 27 comprises a fluid connection 202 connected between the outlet of the expander 24 and the inlet of the first evaporator 25a.

According to a possibility illustrated in , the heat pump comprises two evaporators 25a, 25b arranged in series on the fluidic circuit between the expander 24 and the compressor 26. The fluidic circuit 27 comprises a fluidic connection 203 connected between the outlet of the first evaporator and the inlet of the second evaporator 25 b. According to this possibility, advantageously, the fluidic circuit 27 comprises a fluidic connection 204 connected between the second evaporator outlet 25b and the compressor inlet 26.

According to one possibility, not shown, the heat pump comprises two evaporators 25a, 25b arranged in parallel on the fluidic circuit between the condenser 23 and the compressor 26. Preferably, the heat pump comprises two expanders 24 arranged in parallel on the circuit fluid respectively upstream of each evaporator 25a, 25b. Advantageously, the fluidic circuit 27 comprises a fluidic connection 201 connected between the outlet of the condenser 23 and the inlet of the expander 24. Advantageously, the fluidic circuit 27 comprises a fluidic connection 202 connected between the outlet of the expander 24 and the inlet of the first evaporator 25a. Advantageously, the fluidic circuit 27 comprises a fluidic connection 203 connected between the outlet of the first exchanger 25a and the inlet of the compressor 26. Advantageously, in parallel, the fluidic circuit 27 comprises a fluidic connection connected between the outlet of the condenser 23 and the inlet of the second regulator. Advantageously, the fluidic circuit 27 comprises a fluidic connection connected between the output of the second regulator and the input of the second evaporator 25b. Advantageously, the fluidic circuit 27 comprises a fluidic connection connected between the outlet of the second exchanger 25b and the inlet of the compressor 26. Preferably, the fluidic connections 203 coming from the two evaporators 25a, 25b meet before the inlet of the compressor 26 of so as to ensure a single entry into the compressor 26.

According to the invention, the condenser 23 of the heat pump is arranged on the first steam supply line 2 upstream of the steam generator 6 to transmit calories from the heat transfer fluid to the benefit of liquid water. circulating in the first supply line 2 upstream of the steam generator 6, more precisely the first portion of the first supply line 2.

According to the invention, the first evaporator 25a of the heat pump is arranged on the first evacuation line 4 of the dihydrogen, preferably downstream of the first heat exchange module 5, more precisely downstream of the first heat exchanger 5a of the first heat exchange module 5. Preferably, the first evaporator 25a is arranged upstream of the first processing stage, that is to say upstream of the first air cooler 16. The first evaporator 25a ensures the transfer of energy between the dihydrogen circulating in the first evacuation line 4 and the heat transfer fluid circulating in the fluidic circuit 27 of the heat pump.

According to one embodiment, the heat pump comprises a second heat exchanger 25b. The second heat exchanger 25b is arranged downstream of the first hydrogen treatment stage and advantageously upstream of the second hydrogen treatment stage. Advantageously, the second evaporator 25a is arranged upstream of the second air cooler 19, preferably downstream of the compressor 18.

According to another possibility, not shown, the heat pump comprises a single evaporator 25a, the outlet of which is connected directly to the inlet of the compressor 26 by the fluidic connection 203.

The present invention makes it possible to exploit the waste heat of the system and more particularly the thermal discharges of the dihydrogen produced. The heat pump is an active system allowing the calories taken from the dihydrogen produced to be reinjected upstream of the steam generator and at a temperature above the evaporation temperature of the water.

According to one embodiment, the system comprises a first heat exchanger 9 arranged on the first steam supply line 2 and on the second oxygen evacuation line 3. The first heat exchanger 9 is preferably arranged on the first supply line 2 upstream of the generator 6. The first heat exchanger 9 is arranged on the first portion of the first supply line 2. This first heat exchanger 9 is configured to ensure the heat transfer of calories taken from the flow of oxygen discharged from the electrolyser 1 and circulating in the second discharge line 3 for the benefit of the steam supply line 2. The first heat exchanger 9 is configured to transmit the thermal energy of the oxygen at the outlet of the electrolyser 1 to the liquid water, upstream of the steam generator 6. Preferably, the first heat exchanger 9 is arranged upstream of the condenser 23 .

According to one embodiment, the system comprises a second supply line 10 capable of supplying the electrolyser 1 with air. Preferably, the second supply line 10 regrowth air. According to one possibility, the second supply line 10 is configured to supply air to the electrolyser 1, by which is meant that the second supply line 10 can supply air, the air being for example a gaseous mixture which makes it possible to sweep the cell of the electrolyser 1 and to take away the dioxygen produced by the electrolyser 1 .

According to this embodiment, it is advantageous for the system according to the invention to comprise a second heat exchange module 11 configured to ensure heat exchange between the second air supply line 10 and the second exhaust line 3 of the dioxygen. This heat exchange module 11 is configured to transfer the calories of the dioxygen from the electrolyser 1 to the air intended to supply the electrolyser 1. A flow of dioxygen gas ensures the increase in the temperature of the flow of air which also makes it possible to cool the flow of oxygen evacuated.

The second heat exchange module 11 comprises according to one embodiment at least one heat exchanger 11a configured to ensure the heat transfer from the oxygen to the air. According to a preferred embodiment, the second heat exchange module 11 comprises two heat exchangers 11a, 11b arranged in series between the second supply line 10 and the second evacuation line 3. This arrangement makes it possible to provide a second heat exchanger 11b adapted to the temperature of the oxygen at the outlet of the electrolyser 1, typically around 700° C., and a more usual first heat exchanger 11a adapted to the temperature of the oxygen after passage through a heat exchanger, that is conventionally of the order of 330°C. In this way, the components are optimized for the temperatures and heat transfers to be achieved.

The system preferably comprises a compressor 12 arranged on the second supply line 10 intended for the air supply. The compressor 12 is preferably arranged upstream of the second heat exchange module 11, if present. The compressor 12 is intended to ensure the compression of the air intended to be supplied to the electrolyser 1. The compression of the air advantageously contributes to increasing the temperature of the air before it enters the electrolyser 1.

According to one embodiment, the system comprises means for processing the flow of dihydrogen produced. The dihydrogen produced by the electrolyser 1 and which emerges therefrom via the first evacuation line 4 first of all has a very high temperature corresponding to the reaction temperature of the electrolyser 1. However, with a view to its use, the dihydrogen should preferably be brought to a temperature close to ambient temperature. Furthermore, the dihydrogen evacuated from the electrolyser 1 via the first evacuation line 4 can comprise water vapor carried away with the flow of dihydrogen. It is therefore also preferred to separate the dihydrogen from any water vapor carried away with it, by drying it.

The system according to the invention advantageously comprises for this purpose at least a first stage of treatment intended for the drying and/or compression of the dihydrogen produced.

According to one possibility, the first treatment stage comprises a heat exchanger. The heat exchanger is arranged on the first evacuation line 4, preferably downstream of the first heat exchange module 5. This heat exchanger is according to a first possibility an air cooler 16, that is to say a heat exchanger between a fluid and a gas, the gas being moved by a fan. According to another possibility, the heat exchanger is a standard cooler, that is to say without a fan, this solution being however less effective. According to the possibility not shown in , the heat exchanger is called the second heat exchanger and ensures the heat exchange between the fluid and a gas and in particular the air intended for supplying the electrolyser 1.

The system then comprises a second exchanger arranged on the first evacuation line 4 of the dihydrogen and on the second supply line 10 of air. The fluidic connection 110 is therefore connected between the outlet of the second heat exchanger 16 and the inlet of the compressor 12. In this way, the air intended to enter the electrolyser 1 is preheated by the transfer of calories from the dihydrogen. Preferably, the arrangement of the second heat exchanger corresponds to that of the air cooler 16 described above.

The first treatment stage advantageously comprises a liquid/gas separator 17 arranged downstream of the air cooler 16 or of the second heat exchanger, depending on the embodiment. The separator 17 makes it possible to separate the liquid water from the gaseous dihydrogen, the liquid water resulting from the cooling of the water vapor in the air cooler 16 or in the second heat exchanger below its dew point.

According to a preferred possibility, the system comprises a second stage of treatment arranged downstream of the first stage of treatment on the first evacuation line 4. The second stage of treatment makes it possible to complete the drying of the dihydrogen. The second processing stage advantageously comprises a heat exchanger which, as for the first stage, can be a standard cooler, an air cooler 19 or a third heat exchanger between a fluid (dihydrogen) and the air intended to supply the electrolyser 1. The second stage comprises a liquid/gas separator 20. Preferably, the system comprises between the first stage of treatment and the second stage of treatment a compressor 18 configured to allow the second treatment by the air cooler 19 by previously increasing the temperature of the mix so that it can be cooled again.

At the end of the first treatment stage and/or the second treatment stage, if present, the liquid water is preferably recycled by being returned to the first steam supply line 2 by a recycling line d water 21. The water recycling line is fluidically connected to the first supply line 2, preferably upstream of the steam generator 6, preferably upstream of the first heat exchanger 9, that is to say preferably on the first portion of the first supply line 2. The dihydrogen is itself used and in particular stored after conventional treatments.

According to a possibility not shown, the air cooler 19 is replaced by a heat exchanger. For example, the air cooler 16 of the first stage of treatment is replaced by the second exchanger and the air cooler 19 of the second stage of treatment is replaced by a third exchanger. The third exchanger is arranged on the first evacuation line 4 of the dihydrogen, preferably downstream of the second heat exchanger, and on the second air supply line 10 preferably upstream of the second heat exchanger.

According to one possibility, the system comprises at least one additional heat source configured to heat the water vapor entering the electrolyser 1 up to a predefined target temperature. The additional heat source is advantageously arranged on the first steam supply line 2, preferably downstream of the first heat exchange module 5. The additional heat source is for example an electric heater 14.

According to one possibility, the system comprises at least one additional heat source configured to heat the air entering the electrolyser 1 up to a predefined target temperature. The additional heat source is advantageously arranged on the second air supply line 10, preferably downstream of the second heat exchange module 11. The additional heat source is for example an electric heater 13.

According to one embodiment, the system comprises at least one pump 15 arranged on the first steam supply line 2 configured to set the liquid water in motion in the first portion of the first supply line 2 in upstream of the steam generator 6.

The system preferably comprises a pump 22 on the water recycling line 21. The pump 22 is configured to set in motion the liquid water circulating in the water recycling line 21 and coming from the gas/liquid separator 20.

The electrolyser 1 receives water vapor and advantageously air and rejects dihydrogen and dioxygen.

Preferably, the electrolyser 1 is fluidically connected to the first steam supply line 2. The first steam supply line 2 ensures the fluidic connection of components arranged upstream of the electrolyser 1 on said first supply line 2. The following description is given by starting upstream of the electrolyser 1 and following the direction of circulation in the first supply line. The first supply line 2 ensures the fluid connection of the first heat exchanger 9 then the fluid connection of the first heat exchanger 9 to the condenser 23 of the heat pump, then the fluid connection of the condenser 23 to the steam generator 6, then the connection fluid connection of the steam generator 6 to the first heat exchange module 5, preferably to the first heat exchanger 5a, then the fluid connection of the first heat exchanger 5a to the second heat exchanger 5b, then the fluid connection of the second heat exchanger 5b to the electric heater 14, then the fluidic connection of the electric heater 14 to the electrolyser 1.

Preferably, the electrolyser 1 is fluidically connected to a first evacuation line 4 of dihydrogen. The first evacuation line 4 ensures the fluidic connection of components arranged downstream of the electrolyser 1 on said first evacuation line. The following description is made starting from the electrolyser 1 and following the direction of circulation in the first evacuation line 4 from the electrolyser 1. The first evacuation line 4 ensures the fluidic connection of the electrolyser 1 with the first heat exchange module 5, more preferably with the second heat exchanger 5b, then the fluidic connection of the second heat exchanger 5b to the first heat exchanger 5a, then the fluidic connection of the first heat exchanger 5a to the first evaporator 25a, then the fluidic connection of the first evaporator 25a to the air cooler 16, then the fluidic connection of the air cooler 16 to the liquid/gas separator 17, then the fluidic connection of the liquid/gas separator 17 the compressor 18, then advantageously the fluidic connection of the compressor 18 to the second evaporator 25b, then the fluidic connection of the second evaporator 25b to the air cooler 19, then the fluidic connection of the aero refrigerant 19 to the liquid/gas separator 20.

Preferably, the electrolyser 1 is fluidically connected to a second evacuation line 3 of dioxygen. The second evacuation line 3 ensures the fluidic connection of components arranged downstream of the electrolyser 1 on said second evacuation line 3. The following description is made starting from the electrolyser 1 and following the direction of circulation in the second evacuation line 3 from the electrolyser 1. The second evacuation line 3 ensures the fluidic connection of the electrolyser 1 with the second heat exchange module 11, more preferably with the second heat exchanger 11b, then the fluidic connection of the second heat exchanger 11b to the first heat exchanger 11a, then the fluidic connection of the first heat exchanger 11a to the first heat exchanger 9.

Preferably, the electrolyser 1 is fluidically connected to the second air supply line 10. The second supply line 10 ensures the fluidic connection of components arranged upstream of the electrolyser 1 on said second supply line 10. The second supply line ensures the fluidic connection of the compressor 12 to the first heat exchanger 11a, then the fluidic connection of the first heat exchanger 11a to the second heat exchanger 11b, then the fluidic connection of the second heat exchanger 11b to the electric heater 13, then the fluidic connection of the electric heater 13 to the electrolyser 1. According to a possibility not shown, in upstream of the compressor 12, the second supply line ensures the fluidic connection of the second heat exchanger replacing the air cooler to the compressor 12.

The system includes fluidic connections described below and forming part of the various supply lines 2, 10, and evacuation lines 3, 4 of the system.

Regarding the first supply line 2, it advantageously comprises a fluidic connection A connected to the inlet of the pump 15.

Advantageously, the first supply line 2 comprises a fluidic connection B connected between the outlet of the pump 15 and the inlet of the first heat exchanger 9.

Advantageously, the first supply line 2 comprises a fluidic connection C connected between the outlet of the first heat exchanger 9 and the condenser 23.

Advantageously, the first supply line 2 comprises a fluidic connection D connected between the outlet of the condenser 23 and the inlet of the steam generator 6.

Advantageously, the first supply line 2 comprises a fluidic connection E connected between the outlet of the steam generator 6 and the inlet of the first heat exchanger 5a of the heat exchange module 5.

Advantageously, the first supply line 2 comprises a fluidic connection F connected between the outlet of the first heat exchanger 5a and the inlet of the second heat exchanger 5b.

Advantageously, the first supply line 2 comprises a fluidic connection G connected between the outlet of the second heat exchanger 5b and the inlet of the electric heater 14.

Advantageously, the first supply line 2 comprises a fluidic connection H connected between the output of the electric heater 14 and the input of the electrolyser 1.

Concerning the first evacuation line 4, it advantageously comprises a first fluidic connection I between the outlet of the electrolyser 1 and the inlet of the second heat exchanger 5b of the first heat exchange module 5.

Advantageously, the first evacuation line 4 comprises a fluidic connection J between the outlet of the second heat exchanger 5b of the first heat exchange module 5 and the inlet of the first heat exchanger 5a of the first heat exchange module 5.

Advantageously, the first evacuation line 4 comprises a fluidic connection K between the outlet of the first heat exchanger 5a and the inlet of the first evaporator 25a.

Advantageously, the first evacuation line 4 comprises a fluidic connection L between the outlet of the first evaporator 25a and the inlet of the first air cooler 16.

Advantageously, the first evacuation line 4 includes a fluidic connection M between the first air cooler outlet 16 and the inlet of the separator 17.

Advantageously, the first evacuation line 4 comprises a fluidic connection N between the outlet of the separator 17 and the inlet of the compressor 18.

Advantageously, the first evacuation line 4 comprises a fluidic connection O between the outlet of the compressor 18 and the inlet of the second evaporator 25b.

Advantageously, the first evacuation line 4 comprises a fluidic connection P between the outlet of the second evaporator 25b and the inlet of the air cooler 19.

Advantageously, the first evacuation line 4 comprises a fluidic connection Q between the outlet of the air cooler 19 and the inlet of the separator 20.

Advantageously, the first evacuation line 4 comprises a fluidic connection R ensuring the output of dihydrogen from the separator 20.

Regarding the second evacuation line 3 of dioxygen, it advantageously comprises a fluidic connection 100 between the outlet of the electrolyser 1 and the inlet of the second heat exchanger 11b of the second heat exchange module 11.

Advantageously, the second evacuation line 3 comprises a fluidic connection 101 between the outlet of the second heat exchanger 11b and the inlet of the first heat exchanger 11a of the second heat exchange module 11.

Advantageously, the second evacuation line 3 comprises a fluidic connection 102 between the outlet of the first heat exchanger 11a and the inlet of the first heat exchanger 9.

Advantageously, the second evacuation line 3 comprises a fluidic connection 103 between the outlet of the first heat exchanger 9 and the outside.

Regarding the second air supply line 4, it comprises, according to a possibility not shown, a fluidic connection 110 between the outlet of a second heat exchanger replacing the air cooler 16 and the inlet of the compressor 12.

Advantageously, the second supply line 4 comprises a fluid connection 111 between the outlet of the compressor 12 and the inlet of the first heat exchanger 11a of the second heat exchange module 11.

Advantageously, the second supply line 4 comprises a fluidic connection 112 between the outlet of the first heat exchanger 11a and the inlet of the second heat exchanger 11b of the second heat exchange module 11.

Advantageously, the second supply line 4 comprises a fluidic connection 113 between the outlet of the second heat exchanger 11b and the inlet of the electric heater 13.

Advantageously, the second supply line 4 comprises a fluidic connection 114 between the outlet of the electric heater 13 and the inlet of the electrolyser 1.

In operation, the liquid water arrives in the first steam supply line 2, more precisely in the first portion via the fluidic connection A. The fluidic connection A is advantageously connected to the inlet of the pump 15 which sets the liquid water in motion and advantageously ensures pressurization of the first supply line 2. The water recycling line 21 is advantageously fluidically connected to the first supply line 2 by the fluidic connection B ensuring the fluidic connection from the pump outlet 15 to the inlet in the first heat exchanger 9 through the fluidic connection B. The recycled water and the liquid water enter the first heat exchanger 9. The temperature of the water increases by recovery of the calories of the oxygen circulating in the first heat exchanger 9. The heated water leaves the first heat exchanger 9 through the fluidic connection C and enters, preferably directly, that is to say without o intermediate rgane, in the condenser 23. The temperature of the water increases by recovering calories from the heat transfer fluid of the heat pump circulating in condenser 23. In the condenser, the heat transfer fluid transmits its calories to the water which ensures the condensation of the heat transfer fluid in the condenser 23. The hot liquid water leaves the condenser 23 via the fluidic connection D at a temperature advantageously close to the evaporation temperature, that is to say at +/-5°C and penetrates preferably, directly in the steam generator 6. The liquid water is transformed into steam by the steam generator 6.

According to the invention, the energy to be supplied by the steam generator 6 for the transformation of liquid water into steam is reduced thanks to the thermal energy recovery module and in particular to the condenser 23 of the pump heat and advantageously also to the first heat exchanger 9 ensuring an increase in the temperature of the liquid water by recovery of thermal energy from the dihydrogen and the dioxygen produced by the electrolyser 1.

The steam leaves the steam generator 6 through the fluidic connection E and penetrates, preferably directly, into the first heat exchange module 5, preferably into the first heat exchanger 5a. The water vapor is heated in the first heat exchanger 5a by recovering calories from the dihydrogen circulating in the first heat exchanger 5a. The superheated water vapor leaves the first heat exchanger 5a via the fluidic connection F and enters, preferably directly, into the second heat exchanger 5b. The water vapor is again heated in the second heat exchanger 5b by recovering calories from the dihydrogen circulating in the second heat exchanger 5b. The superheated water vapor leaves the second heat exchanger 5b via the fluidic connection F and penetrates, preferably directly, into the electric heater 14, if necessary. The electric heater 14 provides the last temperature rise that may be necessary for the water vapor to reach a predefined target temperature to enter the electrolyser 1. The water vapor leaves the electric heater 14 through the fluidic connection H and enters, preferably directly, in the electrolyser 1.

The electrolyser 1 is supplied with electric current according to a voltage and a predefined intensity making it possible to ensure the electrolysis and therefore the production of dihydrogen and dioxygen.

The dihydrogen leaves the electrolyser 1 via the first evacuation line, via the fluidic connection I and penetrates, preferably directly, into the first heat exchange module 5, preferably the second heat exchanger 5b. The dihydrogen leaves the electrolyser in the hot gaseous state, it is necessary to lower its temperature to use it and/or store it. The calories of the dihydrogen are therefore recovered by the first supply line and more precisely the steam circulating therein. In the second heat exchanger 5b, the dihydrogen sees its temperature lowered by transfer of calories to the benefit of the water vapor circulating in the second heat exchanger 5b. The cooled dihydrogen leaves the second heat exchanger 5b via the fluidic connection J and penetrates, preferably directly, into the first heat exchanger 5a. In the first heat exchanger 5a, the dihydrogen again sees its temperature lowered by transfer of calories to the benefit of the water vapor circulating in the first heat exchanger 5a. The cooled dihydrogen leaves the first heat exchanger 5a via the fluidic connection K and enters, preferably directly, into the first evaporator 25a. By passing through the first evaporator 25a, the dihydrogen is cooled by promoting the evaporation of the heat transfer fluid circulating in the fluidic circuit 27 in the first evaporator 25a. The dihydrogen leaves the first evaporator 25a through the fluidic connection L and enters, preferably directly, into the first air cooler 16. The dihydrogen leaves the first air cooler 16 through the fluidic connection M and enters, preferably directly, into the liquid/gas separator 17 ensuring the condensation of hydrogen. The dihydrogen leaves the liquid/gas separator 17 via the fluidic connection N and undergoes, if necessary, a new compression with a view to a new condensation. In this case, the dihydrogen leaves the liquid/gas separator 17 through the fluid connection N and enters, preferably directly, into the compressor 18 from where it leaves through the fluid connection O and enters, preferably directly, into the second evaporator 25 b. Passing through the second evaporator 25b, the dihydrogen is cooled by promoting the evaporation of the heat transfer fluid circulating in the fluidic circuit 27 in the second evaporator 25b. The dihydrogen leaves the second evaporator 25 b via the fluidic connection P and penetrates, preferably directly, into the second air cooler 19 ensuring the cooling of the dihydrogen. The dihydrogen leaves the air cooler 19 or a third heat exchanger through the fluidic connection Q and penetrates, preferably directly, into the liquid/gas separator 20 ensuring the condensation of the dihydrogen. The condensed dihydrogen leaves the liquid/gas separator 20 through the fluidic connection R and can be used or stored. The condensed liquid water recovered from the liquid/gas separator 17, 20 can be recycled into the first steam supply line 2 by fluidic connection with the water recycling line 21.

The oxygen produced by the electrolyzer exits through the second evacuation line 3, through the fluidic connection 100 and penetrates, preferably directly, into the second heat exchange module 11, preferably the second heat exchanger 11b. The oxygen comes out of the electrolyser in a hot gaseous state, it is necessary to lower its temperature for discharge into the air. The calories of the dioxygen are therefore advantageously recovered by the second supply line 10 and more precisely the air circulating therein. In the second heat exchanger 11b, the dioxygen sees its temperature lowered by transfer of calories to the benefit of the air circulating in the second heat exchanger 11b. The cooled oxygen leaves second heat exchanger 11b via fluidic connection 101 and enters, preferably directly, into first heat exchanger 11a. In the first heat exchanger 11a, the oxygen again sees its temperature lowered by transfer of heat to the benefit of the air circulating in the first heat exchanger 11a. The cooled oxygen leaves the first heat exchanger 11a via the fluidic connection 102 and advantageously penetrates, preferably directly, into the first heat exchanger 9 of the recovery module. Passing through the first heat exchanger 9, the oxygen again sees its temperature lowered by transfer of calories to the benefit of the liquid water circulating in the first heat exchanger 9. The air leaves the first heat exchanger through the fluidic connection 103 and is released into the air.

According to one possibility, air is supplied to the electrolyser 1. The air arrives via the second supply line 10. Advantageously, the air passes through the second heat exchanger replacing the air cooler 16 and recovers calories from the dihydrogen circulating in the heat exchanger. This first heat exchange ensures a first heating of the air. The air leaves the heat exchanger through the fluidic connection 110 and enters, preferably directly, into the compressor 12. According to the illustrated possibility, the air is compressed by the compressor 12 and its temperature increases. The air enters the compressor 12 through the fluid connection 110. The air leaves the compressor 12 through the fluid connection 111 and enters, preferably directly, into the second heat exchange module 11, preferably into the first heat exchanger 11a. The air is heated in the first heat exchanger 11a by recovering calories from the oxygen circulating in the first heat exchanger 11a. The superheated air leaves the first heat exchanger 11a via the fluidic connection 112 and enters, preferably directly, into the second heat exchanger 11b. The air is again heated in the second heat exchanger 11b by recovering calories from the oxygen circulating in the second heat exchanger 11b. The superheated air leaves the second heat exchanger 11b via the fluidic connection 113 and enters, preferably directly, into the electric heater 13 if necessary. The electric heater 13 provides the last rise in temperature that may be necessary for the air to reach a predefined target temperature to enter the electrolyser 1. The air leaves the electric heater 13 through the fluidic connection 114 and enters, preferably directly, into electrolyser 1.

Fluid connection Temperature
°C Pressure
bar AT 20 B 20 1.8 VS 116 D E 112 F 300 G 614 H 700 I 700 J 330 K 117 I M 45 NOT 45 O P Q 41 R 100 700 101 450 102 230 111 65 1.55 112 350 113 670 114 700 200 130 201 202 90 203 204

By way of example, for 1 kW of electricity consumed by the compressor 26 of the heat pump, 2.5 kW are taken from the first evaporator 25a.

Overall, for example 10.5 MW of electricity from steam generator 6 could be replaced by 7.5 MW of waste heat, only 2.5 MW of electricity remain for steam generator 6.

This solution allows a gain of about 7% on the overall efficiency of electricity to hydrogen conversion.

The invention is not limited to the embodiments described above and extends to all the embodiments covered by the claims.

LIST OF REFERENCES
1 Electrolyser
2 Steam supply line
3 Oxygen evacuation line
4 Dihydrogen evacuation line
5a First heat exchanger of the first heat exchange module
5b Second heat exchanger of the first heat exchange module
6 Steam generator
7 Compressor
9 First heat exchanger
10 Air supply line
11a First heat exchanger of the second heat exchange module
11b Second heat exchanger of the second heat exchange module
12 Compressor
13 Electric heater
14 Electric heater
15 Pump
16 Air cooler
17 Liquid/Gas separator
18 Compressor
19 Air cooler
20 Liquid/Gas Separator
21 Water recycling line
22 Pump
23 Condenser
24 Regulator
25a First evaporator
25b Second evaporator
26 Compressor
27 Fluid circuit
A Fluid connection entering the pump 15
B Fluid connection between the pump 15 and the first heat exchanger 9
C Fluidic connection between the first heat exchanger 9 and the condenser 23
D Fluid connection between condenser 23 and steam generator 6
E Fluidic connection between the steam generator 6 and the first heat exchanger 5a
F Fluidic connection between the first heat exchanger 5a and the second heat exchanger 5b
G Fluidic connection between the second heat exchanger 5 b and the heater 14
H Fluid connection between heater 14 and electrolyser 1
I Fluidic connection between the electrolyser 1 and the second heat exchanger 5 b
J Fluidic connection between the second heat exchanger 5b and the first heat exchanger 5a
K Fluid connection between the first heat exchanger 5a and the first evaporator 25a
L Fluidic connection between the first evaporator 25a and the air cooler 16
M Fluidic connection between the air cooler 16 and the separator 17
N Fluid connection between separator 17 and compressor 18
O Fluidic connection between the compressor 18 and the second evaporator 25 b
P Fluidic connection between the second evaporator 25 b and the air cooler 19
Q Fluidic connection between the air cooler 19 and the separator 20
R Fluidic connection leaving the separator 20
100 Fluidic connection between the electrolyser 1 and the second heat exchanger 11b
101 Fluidic connection between the second heat exchanger 11b and the first heat exchanger 11a
102 Fluidic connection between the first heat exchanger 11a and the first heat exchanger 9
110 Compressor inlet fluid connection 12
111 Fluid connection between the compressor 12 and the first heat exchanger 11a
112 Fluid connection between the first heat exchanger 11a and the second heat exchanger 11b
113 Fluidic connection between the second heat exchanger 11b and the heater 13
114 Fluid connection between heater 13 and electrolyser 1
200 Fluid connection between compressor 26 and condenser 23
201 Fluid connection between condenser 23 and expansion valve 24
202 Fluid connection between expansion valve 24 and first evaporator 25a
203 Fluidic connection between the first evaporator 25a and the second evaporator 25b
204 Fluidic connection between the second evaporator 25 b and the compressor 26

Claims (11)

System including

• a high temperature (EHT) electrolyser (1),
• a first supply line (2) of the electrolyser configured to supply the electrolyser (1) with steam,
• a first evacuation line (4) of the electrolyser configured to evacuate dihydrogen from the electrolyser (1),
• a second exhaust line (3) of the electrolyser configured to evacuate dioxygen from the electrolyser (1),
• a first heat exchange module (5) configured to ensure heat exchange between the first steam supply line (2) and the first dihydrogen evacuation line (4),
• a steam generator (6) arranged on the first steam supply line (2), upstream of the first heat exchange module (5), and configured to produce steam from liquid water,

characterized in that the system comprises a module for recovering the thermal energy from the dihydrogen at the output of the first heat exchange module (5) for the benefit of the first steam supply line (2), the module recovery comprising a heat pump comprising
a fluidic circuit (27) configured to receive a heat transfer fluid,
a first evaporator (25a) arranged on the first evacuation line (2) downstream of the first heat exchange module (5) configured to transfer the thermal energy from the dihydrogen to the heat transfer fluid,
a compressor (26) configured to compress the heat transfer fluid,
a condenser (23) arranged on the first steam supply line (2) upstream of the steam generator (6) and configured to transfer thermal energy from the heat transfer fluid to liquid water,
an expander (24) configured to expand the heat transfer fluid,
the fluidic circuit (27) being configured to fluidically connect the first evaporator (25a) to the compressor (26), the compressor (26) to the condenser (23), the condenser (23) to the expander (24) and the expander (24) to the first evaporator (25a). System according to the preceding claim, in which the heat pump comprises a second evaporator (25b). System according to the preceding claim, in which the second evaporator (25b) is arranged in series on the fluidic circuit (27) of the heat pump downstream of the first evaporator (25a) and preferably upstream of the compressor (26). System according to any one of the two preceding claims comprising at least a first air cooler (16) or a second heat exchanger arranged on the first evacuation line (2) of dihydrogen, downstream of the first evaporator (25a). System according to any one of the three preceding claims comprising at least a second air cooler (19) or a third heat exchanger arranged on the first evacuation line (2) of dihydrogen, downstream of the second evaporator (25b). System according to the preceding claim comprising downstream of the first air cooler (16) or of the second heat exchanger and upstream of the second evaporator (25b) a liquid/gas separator (20). System according to any one of the preceding claims, comprising a first heat exchanger (9) arranged between the second oxygen evacuation line (10) and the first steam supply line (2), upstream of the condenser (23), so as to transmit the thermal energy of the oxygen to the liquid water upstream of the condenser (23). System according to any one of the preceding claims comprising a second supply line (10) of the electrolyser configured to supply the electrolyser (1) with air. System according to the preceding claim comprising a second heat exchange module (11) configured to ensure a heat exchange between the second air supply line (10) and the second oxygen evacuation line (3). System according to any one of the two preceding claims in combination with any one of claims 4 to 6, in which the second heat exchanger is arranged between the first evacuation line (4) of the dihydrogen, downstream of the first evaporator (25a ), and the second air supply line (10). System according to any one of the three preceding claims comprising a compressor (12) arranged on the second air supply line (10) and intended to compress the air, preferably arranged upstream of the second heat exchange module (11 ) and preferably downstream of the second heat exchanger.