Patent Description:
Recently, researches on a generating system using a intermittent energy source such as a solar cell, a wind power and so on, have been developed. In the generating system using the intermittent energy source, the output of power is changed according to the circumstances, and thus a spare power over a necessary power should be properly stored and the stored power should be properly used. For example, a water electrolysis system has been developed. When the spare power over the necessary power is generated from the intermittent energy source generating system, the water electrolysis system is used to generate and to store hydrogen, and then the stored hydrogen is used to provide energy or chemical energy to the fuel cell when the generating system power is decreased.

In a reversible water electrolysis system based on a high temperature water electrolysis and fuel cell technology, a heat source is necessary to form an operating circumstance over about <NUM> and a high temperature vapor. Thus, in the reversible water electrolysis system, the operating circumstance is necessary to be maintained in the high temperature and an exhausted heat exhausted in the water electrolysis system is necessary to be used more efficiently. Accordingly, the system efficiency of the reversible water electrolysis system may be enhanced.

Related prior art includes <CIT> and <CIT>.

The present invention is developed to solve the above-mentioned problems of the related arts. The present invention provides a reversible water electrolysis system capable of increasing system efficiency and capacity using thermal energy more efficiently.

In addition, the present invention also provides a method for operating the reversible water electrolysis system.

According to an example embodiment, the reversible water electrolysis system includes a reversible water electrolysis fuel cell, a first heat exchanger, a steam supply passage, a water discharger and a pump. The reversible water electrolysis fuel cell has a hydrogen pole, an air pole and an electrolyte disposed between the hydrogen pole and the air pole. The reversible water electrolysis fuel cell is configured to be operated at one of a water electrolysis mode and a fuel cell mode. The first heat exchanger is configured to exchange a heat between a first exhaust gas exhausted from the hydrogen pole and a hydrogen or a mixed gas including the hydrogen and a steam. The hydrogen or the mixed gas is supplied to the hydrogen pole. The steam supply passage is configured to supply the steam to the hydrogen pole. The water discharger is configured to removing a water from the first exhaust gas. The pump is equipped to a water discharge passage L43 of the water discharge and is configured to pump the water to outside. The pump is configured to maintain a pressure difference between an inlet of the hydrogen pole and an inlet of the air pole within a predetermined range.

In an example, the reversible water electrolysis system may further include a recycling passage configured to at least partially resupply a gas passing through the water discharger to the hydrogen pole as a recycling gas, a second heat exchanger equipped to the recycling passage and configured to exchange a heat between the recycling gas and the first exhaust gas, and a blower disposed at a downstream of the second heat exchanger <NUM> along the recycling passage.

The second heat exchanger is configured to increase the temperature of the recycling gas to be a predetermined range.

In an example, the reversible water electrolysis system may further include a third heat exchanger configured to exchange a heat between an outer supply water supplied from outside and the first exhaust gas. The outer supply water evaporated to be the steam at the third heat exchanger may inflow to the steam supply passage.

In an example, a conflux between the steam supply passage and a hydrogen supply passage supplying the hydrogen to the hydrogen pole may be disposed between the first heat exchanger and the hydrogen pole, or at a front side of the first heat exchanger.

In an example, the reversible water electrolysis system may further include first and second blowers and connected in parallel with an air supply passage which supplies the air to the air pole, and a fourth heat exchanger configured to exchange a heat between the air supplied to the air pole via the air supply passage and a second exhaust gas exhausted at the air pole. The second blower is configured to supply the air more than the first blower.

In an example, the reversible water electrolysis system may further include a feedback passage configured to connect the air supply passage with an exhaust passage of the air pole, and a third blower equipped to the feedback passage. The second exhaust gas may be partially recycled to the air pole via the feedback passage.

In an example, the first blower may be operated at the water electrolysis mode, and the second blower and the third blower may be operated at the fuel cell mode.

In an example, the reversible water electrolysis system may further include a bifurcation passage configured to partially bifurcate the first exhaust gas, to supply the bifurcated first exhaust gas to an exhaust passage of the air pole, and a catalytic combustor equipped at a conflux between the bifurcation passage and the exhaust passage of the air pole. The catalytic combustor may heat the second exhausted from the air pole.

In an example, the bifurcation passage may be closed at the water electrolysis mode, and the bifurcation passage may be open at the fuel cell mode.

According to another example embodiment, in a method for operating a reversible water electrolysis system, the reversible water electrolysis system is operated at a water electrolysis mode and a fuel cell mode using a reversible water electrolysis fuel cell having a hydrogen pole and an air pole. In the method, a heat is exchanged between a first exhaust gas and a hydrogen so as to heat the hydrogen using the first exhaust gas, at a first heat exchanger. A water is separated from the first exhaust gas passing through the first heat exchanger. The separated water is discharged to outside using a drain pump. The first exhaust gas from which the water is removed is at least partially recycled to the hydrogen pole as a recycling gas.

In an example, in the discharging the separated water, an operation of the drain pump may be controlled to maintain a pressure difference between an inlet of the hydrogen pole and an inlet of the air pole within a predetermined range.

In an example, a second heat exchanger and a blower may be sequentially equipped along a passage for recycling the recycling gas. The second heat exchanger may exchange a heat between the recycling gas and the first exhaust gas passing through the first heat exchanger, to heat the recycling gas.

In an example, in the method, a heat may be exchanged between an air supplied from one of first and second blowers and a second exhaust gas exhausted from the air pole, to heat the air. A capacity of the second blower may be larger than that of the first blower. The heated air may be supplied to the air pole. The second exhaust gas exhausted from the air pole may be at least partially resupplied to the air pole, using a third blower.

In an example, at the water electrolysis mode, the first blower may be operated, and at the fuel cell mode, the second blower and the third blower may be operated.

In an example, in the method, a heat may be exchanged between an air supplied from one of first and second blowers and a second exhaust gas exhausted from the air pole, to heat the air. A capacity of the second blower may be larger than that of the first blower. The heated air may be supplied to the air pole. The first exhaust gas exhausted from the hydrogen pole may be partially bifurcated via a bifurcation passage, to interflow to the second exhaust gas. The second exhaust gas mixed with the first exhaust gas may be heated using a catalytic combustor.

In an example, the bifurcation passage may be closed at the fuel cell mode, and the bifurcation passage may be open at the fuel mode.

According to the present example embodiments, the water is separated from the exhaust gas exhausted from the hydrogen pole of the fuel cell and then the water is discharged using the drain pump. Here, the operation of the drain pump is properly controlled to maintain a pressure difference between the inlet of the hydrogen pole of the fuel cell and the inlet of the air pole within a predetermined range, so that the fuel cell may be operated stably and more efficiently.

In addition, the exhaust gas exhausted from the air pole is partially resupplied to the air pole, or the exhaust gas exhausted from the air pole is heated using the exhaust gas from the hydrogen pole, so that a balance of plant (BOP) may be minimized and power consumption may be decreased to enhance an efficiency of the system.

In addition, an exhaust gas from the hydrogen pole is partially used as a fuel of the catalytic combustor so as for heating the exhaust gas of the air pole, so that the temperature of the exhaust gas of the air pole is increased and an increased energy is transmitted to the air. Thus, power consumption of a heat for heating the air supplied to the air pole may be decreased and system efficiency may be increased.

The invention is described more fully hereinafter with Reference to the accompanying drawings, in which embodiments of the invention are shown. Rather, these embodiments are provided so that this disclosure will be thorough and complete, and will fully convey the scope of the invention to those skilled in the art. In the drawings, the size and relative sizes of layers and regions may be exaggerated for clarity.

<FIG> is a schematic diagram illustrating a reversible water electrolysis system according to a first example embodiment of the present invention.

Referring to <FIG>, the reversible water electrolysis system according to the present example embodiment includes a steam generator <NUM>, a reversible water electrolysis fuel cell <NUM>, heaters <NUM> and <NUM>, a plurality of passages connecting the above mentioned elements, a plurality of heat exchangers disposed at the passages, a blower, and a pump.

The reversible water electrolysis fuel cell <NUM> is operated at one of a water electrolysis mode and a fuel cell mode. At the water electrolysis mode, hydrogen and oxygen are generated using a steam and an electricity provided from outside. At the fuel cell mode, the electricity and a water are generated using a chemical reaction between the hydrogen and the oxygen provided from outside.

The reversible water electrolysis fuel cell <NUM> may be performed as an arbitrary fuel cell such as solid oxide fuel cell (SOFC), molten carbonate fuel cell (MCFC), and so on. For convenience of explanation, hereinafter, the reversible water electrolysis fuel cell <NUM> is assumed to be performed as the SOFC.

The reversible water electrolysis fuel cell <NUM> includes a hydrogen pole <NUM>, an air pole <NUM> and an electrolyte disposed between the hydrogen pole <NUM> and the air pole <NUM>.

At the water electrolysis mode (hereinafter, a SOEC mode), a steam H<NUM>O is supplied to the hydrogen pole <NUM> from outside, and the hydrogen pole <NUM> generates hydrogen H<NUM>. The hydrogen pole <NUM> receives the steam H<NUM>O via a passage L21 and generates the hydrogen Hz, and the hydrogen pole <NUM> exhausts a gas including the generated hydrogen H<NUM> and the steam H<NUM>O not transformed into the hydrogen H<NUM> via a passage L41, as a first exhaust gas.

At the SOEC mode, the air pole <NUM> receives the oxygen O<NUM> from the hydrogen pole <NUM>, and transfers the oxygen O<NUM> via a passage L53 using an air supplied from outside. The air pole <NUM> exhausts a gas including the oxygen O<NUM> and the air via a passage L61, as a second exhaust gas.

At the fuel cell mode (hereinafter, a SOFC mode), the hydrogen pole <NUM> generates a water (steam) via a chemical reaction between the hydrogen supplied from the passage L11 and the oxygen supplied from the air pole <NUM>, and the hydrogen pole <NUM> exhausts a gas including the generated steam and the hydrogen not transformed into the steam, as an exhaust gas.

At the SOFC mode, the air pole <NUM> receives the air via the passage L53 and supplies the oxygen to the hydrogen pole <NUM> via the electrolyte. The air pole <NUM> exhausts nitrogen N<NUM> and the air via the passage L61, as the second exhaust gas.

Theoretically, at the SOEC mode, the water (steam) and the electricity are supplied to the fuel cell <NUM>, and at the SOFC mode, the hydrogen and the oxygen are supplied to the fuel cell <NUM>. However, in an actual operation for the system, to increase fuel cell performance and to avoid damage to the SOFC fuel cell at each of the SOEC mode and the SOFC mode, the mixed gas including the hydrogen and the steam may be supplied to the fuel cell <NUM>.

Here, at the SOEC mode, the steam is mainly required and thus the mixed gas in which the steam and the hydrogen are mixed by a mass ratio of <NUM>:<NUM> (a volume ratio of about <NUM>:<NUM>) is supplied to the fuel cell <NUM>. At the SOFC mode, the hydrogen is mainly required and thus the mixed gas in which the hydrogen and the steam are mixed by a mass ratio of <NUM>:<NUM> (a volume ratio of about <NUM>:<NUM>) is supplied to the fuel cell <NUM>.

The mixed ratio between the steam and the hydrogen may be variously changed at each of the SOEC mode and the SOFC mode. In addition, to control the mixed ratio between the steam and the hydrogen differently according to the selected mode, although not shown in the figure, the blower, the pump or/and a flow control valve may be equipped at at least one of the hydrogen supply passage L11 and the steam supply passage L21 to control an amount of the supplied hydrogen or/and an amount of the supplied steam.

In the present example embodiment, the hydrogen is supplied to the fuel cell <NUM> via the hydrogen supply passage L11. For example, the hydrogen supply passage L11 may be connected to a hydrogen storage tank (not shown). The hydrogen flowed into the hydrogen supply passage L11 is heated at a first heat exchanger <NUM>. The first heat exchanger <NUM> exchanges a heat between the hydrogen supplied to the hydrogen pole <NUM> of the fuel cell <NUM> and the exhaust gas exhausted from the hydrogen pole <NUM>. Here, the hydrogen supplied to the hydrogen pole <NUM> may be at a room temperature or a temperature between <NUM> and <NUM>. The exhaust gas exhausted from the hydrogen pole <NUM> may be at a temperature between <NUM> and <NUM>. The hydrogen supplied to the hydrogen pole <NUM> may be heated into a temperature of about <NUM> or more, at the first heat exchanger <NUM>.

The steam is supplied to the fuel cell <NUM> via the steam supply passage L21. The steam generator <NUM> connected to the steam supply passage L21, may include a pump <NUM> and a boiler <NUM>. The water which is supplied to the boiler <NUM> by the pump <NUM> is heated to generate the steam. Here, the boiler <NUM> may be performed as the conventional combustion device or incinerator such as a boiler system, a cogeneration system, a combined power generation system, a waste incineration system and so on.

The steam supply passage L21 interflows to the hydrogen supply passage L11, and the mixed gas of the hydrogen and the steam is supplied to the hydrogen pole <NUM> of the fuel cell <NUM> via a mixed gas supply passage L12. Here, from a view point of the hydrogen supply passage L11, the conflux between the steam supply passage L21 and the hydrogen supply passage L11 may be disposed between the first heat exchanger <NUM> and the hydrogen pole <NUM>, at a downstream side of the first heat exchanger <NUM>. Thus, the high temperature exhaust gas exhausted from the hydrogen pole <NUM> merely heats the hydrogen at the first heat exchanger <NUM> without re-heating the steam heated with a high temperature, so that the hydrogen may be heated more, compared to the heating of the mixed gas having the hydrogen and the steam,.

Alternatively, although not shown in the figure, from a view point of the hydrogen supply passage L11, the conflux between the steam supply passage L21 and the hydrogen supply passage L11 may be disposed at a front side of the first heat exchanger <NUM>.

The reversible water electrolysis system according to the present example embodiment may further include a first heater <NUM>. The first heater <NUM> is disposed adjacent to an inlet of the hydrogen pole <NUM> and is disposed at the mixed gas supply passage L12. The first heater <NUM> heats the mixed gas of the hydrogen and the steam to be a predetermined range of temperature, so as for the fuel cell <NUM> to be operated with an optimized efficiency at both of the SOEC mode and the SOFC mode.

For example, the first heater <NUM> may heat the mixed gas of the hydrogen and the steam to be the temperature between <NUM> and <NUM>. In addition, although not shown in the figure, to control the above heating temperature, at least one temperature sensor may be disposed at an inside, a front side or a rear side of the first heater <NUM> to measure the temperature of the mixed gas, and the mixed gas may be heated based on the measured temperature.

The reversible water electrolysis system according to the present example embodiment may further include an air supply passage L53 and an air-exhaust gas heat exchanger <NUM> disposed at the air supply passage L53. An air is supplied from outside to the air pole <NUM> via the air supply passage L53. The air-exhaust gas heat exchanger <NUM> exchanges a heat between the air supplied to the air pole <NUM> via the air supply passage L53 and the exhaust gas exhausted from the air pole <NUM> and transferred to the exhaust passage L61.

A second heater <NUM> may be equipped at the air supply passage L53. The second heater <NUM> is disposed adjacent to the air pole <NUM> and is disposed at the air supply passage L53. The second heater <NUM> heats the air into a predetermined range of temperature, so as for the fuel cell <NUM> to be operated with the optimized efficiency. For example, the heat exchanger <NUM> may heat the air of room temperature into a temperature between <NUM> and <NUM>, and then the second heater <NUM> may heat the heated air into a temperature between <NUM> and <NUM>. Then, the air may be supplied to the air pole <NUM>.

In the present example embodiment, a first bifurcation passage L51 and a second bifurcation passage L52 which are connected in parallel, are connected to an upstream of the air supply passage L53. A first blower <NUM> is equipped to the first bifurcation passage L51, and a second blower <NUM> is equipped to the second bifurcation passage L52.

An amount of air transferred via the second bifurcation passage L52 is larger than that via the first bifurcation passage L51. For example, a diameter of a conduit of the second bifurcation passage L52 may be larger than that of the first bifurcation passage L <NUM>, and thus the second blower <NUM> supplies the air more than the first blower <NUM>. Here, the amount of the air via the second bifurcation passage L52 may be larger than that via the first bifurcation passage L51, by five to fifteen times.

At the SOEC mode, the water (steam) and the electricity are necessary larger than the air, but at the SOFC mode, the hydrogen and the oxygen (air) are necessary larger than the water and the electricity. Thus, at the SOEC mode, the first blower <NUM> is only operated and the second blower <NUM> is not operated. However, at the SOFC mode, the second blower <NUM> is only operated and the first blower <NUM> is not operated. Alternatively, at the SOFC mode, both of the first and second blowers <NUM> and <NUM> may be operated.

The exhaust gas exhausted at the hydrogen pole <NUM> of the fuel cell <NUM> is exhausted to outside via the exhaust passage L41. Here, the first heat exchanger <NUM> and the second heat exchanger <NUM> are sequentially equipped along the exhaust passage L41. The exhaust gas transmits thermal energy to the hydrogen supplied to the hydrogen pole <NUM> via the hydrogen supply passage L11, to heat the hydrogen, at the first heat exchanger <NUM>.

The exhaust gas transferring via the exhaust passage L41 is transferred to a water discharger. The water discharger separates the water from the exhaust gas. In the present example embodiment, the water discharger may include a pump, a cooling device and so on which is equipped to a circulation passage L70 of a refrigerant passing through and circulating a condenser <NUM> and a drain <NUM>.

The water of the exhaust gas is condensed at the condenser <NUM>, and the condensed water is discharged to outside via the water discharge passage L42 and L43 at the drain <NUM>. The remaining gas (hydrogen and steam) not condensed to the water is transferred via the passage L45, and is separated into the hydrogen and the steam via a blower <NUM>, a compressor <NUM> and a hydrogen separator <NUM>, and then each of the hydrogen and the steam is individually treated.

The water discharger illustrated in the figure is an example, and thus the method for separating and discharging the water from the exhaust gas, the method for extracting the hydrogen, and the devices for performing the methods may be variously changed.

In the present example embodiment, the gas passing through the drain <NUM> and transferring via the passage L45 is at least partially bifurcated by the recycling passage L44. The recycling passage L44 is connected to the hydrogen supply passage L11, and thus the gas bifurcated via the recycling passage L44 may be resupplied to the hydrogen pole <NUM> as a recycling gas.

For example, at the SOFC mode, the gas in the passage L45 may be at least partially recycled to the recycling passage L44 to be supplied to the hydrogen pole <NUM>, and at the SOEC mode, the recycling passage L44 may be closed. For performing the above, a <NUM>-way valve may be equipped at a bifurcation point of the recycling passage L44, or an on-off valve may be equipped at an arbitrary position of the recycling passage L44.

In the present example embodiment, the second heat exchanger <NUM> and a blower <NUM> may be equipped at the recycling passage L44. Here, the second heat exchanger <NUM> and the blower <NUM> are sequentially equipped at the recycling passage L44 from an upstream toward a downstream of the recycling passage L44.

The second heat exchanger <NUM> exchanges a heat between the exhaust gas of the exhaust passage L41 and the recycling gas of the recycling passage L44, to heat the recycling gas. In the present example embodiment, the second heat exchanger <NUM> may be a mini heat exchanger for increasing the temperature of the recycling gas to prevent the recycling gas from being condensed. The recycling gas bifurcated into the recycling passage L44 is saturated, and thus the devices like the blower <NUM> may be damaged if even a little recycling gas is condensed due to the circumstances of the recycling passage L44. In addition, the durability of the devices like the blower <NUM> may be decreased if the recycling gas is heated too much at the second heat exchanger <NUM>.

Thus, in the present example embodiment, the mini second heat exchanger <NUM> is equipped at a front (upstream) of the blower <NUM>, to increase the temperature of the recycling gas slightly and to be transferred to the blower <NUM>. The increased temperature of the recycling gas increased by the second heat exchanger <NUM> may depend on the amount of the recycling gas. For example, the temperature of the recycling gas may be increased within a range between about <NUM> and <NUM>.

The recycling gas sequentially passing through the second heat exchanger <NUM> and the blower <NUM> interflows at the hydrogen supply passage L11, and is heated to be a relatively high temperature with the hydrogen at the first heat exchanger <NUM>, and then is supplied to the hydrogen pole <NUM> of the fuel cell <NUM>.

In the present example embodiment, the reversible water electrolysis system may further include a drain pump <NUM> equipped at the water discharge passage L43. The drain pump <NUM> forces to pump the water discharged via the passage L42 at the drain <NUM>, to discharge the water to outside.

As the drain pump <NUM> is equipped to the water discharge passage L43, the pressure difference between the inlet of the hydrogen pole <NUM> and the inlet of the air pole <NUM> is removed or decreased within a predetermined range.

As the pressure difference between the inlet of the hydrogen pole <NUM> and the inlet of the air pole <NUM> is decreased, the fuel cell system may be operated more stably and more efficiently. However, in the conventional fuel cell system, many passages or heat exchanges are equipped at the inlet and the outlet of the hydrogen pole <NUM> compared to the air pole <NUM>, and thus the pressure of the hydrogen pole <NUM> is more increased. In contrast, in the present example embodiment, as the drain pump <NUM> is operated, the absorbing force of the pump <NUM> is applied to the hydrogen pole <NUM> via the exhaust passage L41 of the hydrogen pole <NUM>, and thus the pressure at the inlet of the hydrogen pole <NUM> may be decreased.

Thus, to control the operation of the pump <NUM>, the pressure of the inlet of the hydrogen pole <NUM> is maintained to be substantially same as or be in a predetermined range with that of the inlet of the air pole <NUM>, so that the system may be stably and efficiently operated.

In addition, as the pressure of the inlet of the hydrogen pole <NUM> is decreased, the capacity of the pump or the blower for transferring the hydrogen to the hydrogen pole <NUM> via the hydrogen supply passage L11 may be decreased. In addition, even though the pressure inside of the exhaust passage L41 is decreased to be lower than an atmospheric pressure, the water is prevented from flowing back to the exhaust passage L41 since the pump <NUM> forces to discharge the water.

Hereinafter, referring to <FIG> and <FIG>, the SOEC mode and the SEFC mode of the reversible water electrolysis system according to the first example embodiment are explained.

<FIG> is a schematic diagram illustrating a SOEC mode of the reversible water electrolysis system of <FIG>. In <FIG>, the passages used at the SOEC mode are illustrated as a bold line.

Referring to <FIG>, at the SOEC mode, the steam is supplied to the hydrogen pole <NUM> of the fuel cell <NUM> via the steam supply passage L21 and the passage L21. At the SOEC mode, a relatively small amount of hydrogen is necessary, and thus additional hydrogen is not supplied via the hydrogen supply passage L11, but at the initial time, the hydrogen may be supplied a little.

In addition, a small amount of air is necessary at the SOEC mode, and thus the first blower <NUM> is operated to supply the air to the air pole <NUM> of the fuel cell <NUM> and the second blower <NUM> is not operated.

As the water electrolysis reaction occurs at the fuel cell <NUM>, the first exhaust gas including the hydrogen and the steam is exhausted from the hydrogen pole <NUM> to the exhaust passage L41, and the second exhaust gas including the oxygen and the air is exhausted from the air pole <NUM> to the exhaust passage L61.

The first exhaust gas exhausted to the exhaust passage L41 exchanges a heat with the recycling gas at the first and second heat exchangers <NUM> and <NUM>, so that the recycling gas is heated. Here, the recycling gas is resupplied to the hydrogen pole <NUM> via the recycling passage L44. Then, the first exhaust gas is transferred to the water discharger, the steam is condensed to be discharged to outside via the water discharge passage L43, and the mixed gas having the hydrogen and the uncondensed steam is partially resupplied to the hydrogen pole <NUM> via the recycling passage L44 as the recycling gas. Here, the remaining of the mixed gas not supplied to the hydrogen pole <NUM> is transferred via the exhaust passage L45, to be independently separated and stored.

Here, a ratio of the amount of the mixed gas bifurcated into each of the recycling passage L44 and the exhaust passage L45 may be variously changed, and for example, the ratio may be <NUM>:<NUM> to <NUM>:<NUM>. That is, the ratio of the amount of the mixed gas flowed to the recycling passage L44 and that flowed to the exhaust passage L45 may be <NUM>:<NUM> to <NUM>:<NUM>.

<FIG> is a schematic diagram illustrating a SOFC mode of the reversible water electrolysis system of <FIG>. In <FIG>, the passages used at the SOFC mode are illustrated as a bold line.

Referring to <FIG>, at the SOFC mode, the hydrogen is supplied via the hydrogen supply passage L11 and a little amount of steam is supplied via the steam supply passage L21. Alternatively, no steam is required in the steam supply passage L21. The hydrogen is heat-exchanged with the exhaust gas of the exhaust passage L41 at the first heat exchanger <NUM>, and the hydrogen is heated and mixed with the steam. Then, the mixed gas of the steam and the hydrogen is supplied to the hydrogen pole <NUM> via the mixed passage L12.

At the SOFC mode, a large amount of air is necessary, and thus the second blower <NUM> is operated to supply the air to the air pole <NUM> and the first blower <NUM> is not operated. Alternatively, both of the first and second blowers <NUM> and <NUM> may be operated.

As the chemical reaction between the hydrogen and the oxygen occurs at the fuel cell <NUM>, the first exhaust gas including the steam and the hydrogen is exhausted via the exhaust passage L41 from the hydrogen pole <NUM>, and the second exhaust gas including the nitrogen and the oxygen is exhausted via the exhaust passage L61 from the air pole <NUM>.

The first exhaust gas exhausting to the exhaust passage L41 exchanges a heat with the recycling gas at the first and second heat exchangers <NUM> and <NUM>, so that the recycling gas is heated. Here, the recycling gas is resupplied to the hydrogen pole <NUM> via the recycling passage L44. Then, the first exhaust gas is transferred to the water discharger, the steam is condensed to be discharged to outside via the water discharge passage L43, and the mixed gas including the hydrogen and the uncondensed steam is resupplied to the hydrogen pole <NUM> via the recycling passage L44 as the recycling gas.

According to the first example embodiment referring to <FIG>, the properly mixed gas of hydrogen and steam is supplied to the fuel cell <NUM> according to each operating mode of the reversible water electrolysis system.

For example, at the SOEC mode, a relatively small amount of hydrogen is necessary, and thus the exhaust gas exhausted to the exhaust passage L41 is partially bifurcated into the recycling passage L44, and the hydrogen included in the recycling gas feedback through the recycling passage L44 is used. Thus, the hydrogen is unnecessary to be additionally supplied from outside to the hydrogen supply passage L11, and the air is merely supplied by only operating the first blower <NUM> which is relatively mini size since a relatively small amount of air is also necessary.

In contrast, at the SOFC mode, the remaining exhaust gas except for the condensed water of the exhaust gas exhausted to the exhaust passage L41 is resupplied via the recycling passage L44 as the recycling gas, so that the hydrogen not reacted and wasted at the fuel cell <NUM> may be minimized.

In addition, the operation of the pump <NUM> is controlled at each of the SOEC mode and the SOFC mode, to maintain the pressure of the inlet of the hydrogen pole <NUM> and the pressure of the inlet of the air pole <NUM> to be substantially same with each other or to be in a predetermined range, so that the system may be operated more stably and more efficiently. In addition, the second heat exchanger <NUM> is equipped at the upstream side of the blower <NUM> of the recycling passage L44, and thus the blower <NUM> may be prevented from being damaged due to the condense of the steam inside of the recycling passage L44.

<FIG> is a schematic diagram illustrating a reversible water electrolysis system according to a second example embodiment of the present invention.

The reversible water electrolysis system according to the present example embodiment is substantially same as the reversible water electrolysis system in <FIG> except that a water supply passage L31, a pump <NUM> equipped at the passage L31 and a third heat exchanger are further included, and thus same references are used for the same elements and any repetitive explanation will be omitted. Here, the water supply passage L31 supplies a water from outside (hereinafter, an outer supply water).

Referring to <FIG>, in the reversible water electrolysis system according to the present example embodiment, the third heat exchanger <NUM> exchanges a heat between the outer supply water supplied to the passage L31 and the exhaust gas exhausted from the hydrogen pole <NUM>, and the second heat exchanger <NUM> may be disposed at a downstream of the first heat exchanger <NUM> from a view point of a flow of the exhaust gas.

For example, the outer supply water may be at a temperature between a room temperature and <NUM>. The exhaust gas supplied to the third heat exchanger <NUM> may be at a temperature between <NUM> and <NUM>. The outer supply water may be evaporated and heated into a temperature of about <NUM> or more, at the third heat exchanger <NUM>. The steam evaporated at the third heat exchanger <NUM> interflows to the steam supply passage L21, and then is supplied to the hydrogen pole <NUM> via the passages L21 and L12.

Accordingly, the water supply passage L31 receiving the water from outside and the third heat exchanger <NUM> are further included, and thus a waste heat recovery rate for the exhaust gas exhausted from the hydrogen pole may be more increased. In the previous first example embodiment, the exhaust gas at the exhaust passage L41 is maintained with a relatively high temperature after the exhaust gas passes through the first heat exchanger <NUM> and the second heat exchanger <NUM> mentioned below. Here, for example, at the SOEC mode, the exhaust gas passing through the second heat exchanger <NUM> may be at the temperature of <NUM> or more. However, in the present example embodiment, the exhaust gas of the exhaust passage L41 heats the outer supply water at the third heat exchanger <NUM>, so that the exhaust gas passing through the second heat exchanger <NUM> may be cooled down to the temperature between <NUM> and <NUM>. Thus, the waste heat recovery rate for the exhaust gas may be more increased.

Hereinafter, referring to <FIG> and <FIG>, the operation at each of the SOEC mode and the SOFC mode is explained in detail, for the reversible water electrolysis system according to the present example embodiment.

The reversible water electrolysis system according to the present example embodiment is substantially same as the reversible water electrolysis system in <FIG> except that the outer supply water is additionally supplied via the water supply passage L31.

Referring to <FIG>, at the SOEC mode, the steam generated at the steam generator <NUM> is supplied via the steam supply passage L21, and at the same time, the outer supply water is supplied via the outer supply passage. The outer supply passage is evaporated at the third heat exchanger <NUM> to be a steam having a relatively high temperature, and then the high temperature steam interflows to the steam supply passage L21. The mixed steam is supplied to the hydrogen pole <NUM> via the passages L21 and L12.

At the SOEC mode, a relatively small amount of hydrogen is necessary, and thus the additional hydrogen is not supplied via the hydrogen supply passage L11. In addition, a relatively small amount of air is necessary, and thus the first blower <NUM> is operated but the second blower <NUM> is not operated.

As the water electrolysis reaction occurs at the fuel cell <NUM>, the first exhaust gas including the hydrogen and the steam is exhausted from the hydrogen pole <NUM> via the exhaust passage L41, and the second exhaust gas including the oxygen and the air is exhausted from the air pole <NUM> via the exhaust passage L61.

The first exhaust gas exhausted to the exhaust passage L41 sequentially heats the downstream recycling gas, the outer supply water and the upstream recycling gas, with sequentially passing through the first heat exchanger <NUM>, the third heat exchanger <NUM> and the second heat exchanger <NUM>, and then the first exhaust gas is transferred to the water discharger. At the water discharger, the steam of the first exhaust gas is condensed to be discharged to outside via the water discharge passage L43, and the mixed gas of the hydrogen and the uncondensed steam is partially resupplied to the hydrogen pole <NUM> via the recycling passage L44 as the recycling gas, and then the remaining gas of the mixed gas is transferred via the exhaust passage L45 to be independently separated and treated.

A ratio of the amount of the mixed gas bifurcated into each of the recycling passage L44 and the exhaust passage L45 may be variously changed, and for example, the ratio may be <NUM>:<NUM> to <NUM>:<NUM>. That is, the ratio of the amount of the mixed gas flowed to the recycling passage L44 and that flowed to the exhaust passage L45 may be <NUM>:<NUM> to <NUM>:<NUM>.

The operation at the SOFC mode is substantially same as the operation of the SOFC at the previous first example embodiment referring to <FIG>.

Referring to <FIG>, at the SOFC mode, the hydrogen is supplied via the hydrogen supply passage L11, and a relatively small amount of steam is supplied via the steam supply passage L21. Since the small amount of steam is necessary, the outer supply water is not supplied via the water supply passage L31.

The hydrogen is heated via the heat-exchange with the exhaust gas of the exhaust passage L41 at the first heat exchanger <NUM>, and then the heated hydrogen is mixed with the steam. Then, the mixed gas having the steam and the hydrogen is supplied to the hydrogen pole <NUM>.

At the SOFC mode, a relatively large amount of air is necessary, and thus the second blower <NUM> for supplying the air to the air pole <NUM> is operated but the first blower <NUM> is not operated. Alternatively, both of the first and second blowers <NUM> and <NUM> may be operated.

The first exhaust gas exhausted from the hydrogen pole <NUM> exchanges a heat with the recycling gas at the first and second heat exchangers <NUM> and <NUM>, so that the recycling gas is heated. Then, the first exhaust gas is transferred to the water discharger, the steam is condensed to be discharged to outside via the water discharge passage L43, and the mixed gas including the hydrogen and the uncondensed steam is resupplied to the hydrogen pole <NUM> via the recycling passage L44 as the recycling gas.

Hereinafter, referring to <FIG> and <FIG>, the reversible water electrolysis systems according to third and fourth present example embodiments of the present invention are explained in detail.

<FIG> is a schematic diagram illustrating a reversible water electrolysis system according to a third example embodiment of the present invention.

The reversible water electrolysis system according to the present example embodiment is substantially same as the reversible water electrolysis system in <FIG> except that a feedback passage L62 and a blower equipped at the feedback passage <NUM> are further included. Here, the feedback passage L62 connects the air supply passage L53 with the air exhaust passage L61.

Referring to <FIG>, in the present example embodiment, the feedback passage L62 connects an upstream side of the heat exchanger <NUM> of the air exhaust passage L61 with a downstream side of the heat exchanger <NUM> of the supply passage L53.

Accordingly, the exhaust gas exhausting along the exhaust passage L61 from the air pole <NUM> is partially recycled to the blower <NUM>. For example, a half of the exhaust gas in the exhaust passage L61 may be bifurcated to the feedback passage L62, but not limited thereto and an amount of the bifurcated exhaust gas may be variously changed. The recycled exhaust gas passing through the blower <NUM> is mixed with the air flowed via the air supply passage L51 and/or L52, and then is supplied to the air pole <NUM>.

Conventionally, the air flowed via the air supply passage L51 and/or L52 is heated at the air-exhaust heat exchanger <NUM>, but the air is additionally heated at the second heater <NUM> because of an insufficient heating energy. However, as the amount of the supplied air increases (for example, as for the SOFC mode), the power consumption at the second heater <NUM> is also increased, so that the system efficiency may be entirely decreased.

Thus, in the present example embodiment, the high temperature exhaust gas exhausted from the air pole <NUM> is mixed with the air via the feedback passage L62, and thus relatively high temperature air may be supplied to the air pole <NUM> and the second heater <NUM> may not be operated. Thus, the power consumption may be also decreased. For example, as the experimental results at the SOFC mode, the power consumption of the blower <NUM> according to the present example embodiment was decreased by <NUM>/<NUM>, compared to the second heater <NUM> at the first example embodiment or the second example embodiment.

In addition, the air supplied to the air pole <NUM> is partially filled with the recycling gas in the feedback passage L62, so that, at the SOFC mode, the amount of the air supplied to the bifurcation passage L52 is decreased, and the amount of the air treated in the second blower <NUM> is also decreased. Thus, the air-exhaust gas heat exchanger <NUM> may be minimized and the power consumption at system auxiliary equipment (a balance of plant, BOP) adjacent to the air pole <NUM> may be decreased, to enhance the energy efficiency of the entire system.

<FIG> is a schematic diagram illustrating a reversible water electrolysis system according to a fourth example embodiment of the present invention.

The reversible water electrolysis system according to the present example embodiment is substantially same as the reversible water electrolysis system in <FIG> except that a bifurcation passage L46 and a catalytic combustor <NUM> are further included. Here, the bifurcation passage L46 connects the exhaust passage L41 of the hydrogen pole L41 with the exhaust passage L61 of the air pole, and the catalytic combustor <NUM> is equipped at the conflux between the bifurcation passage L46 and the exhaust passage L61 of the air pole.

Referring to <FIG>, the catalytic combustor <NUM> induces the exhaust gas exhausted from the air pole <NUM> and the exhaust gas of the hydrogen pole bifurcated via the bifurcation passage L46, to pass through a carrier carrying a metal or a metal oxide catalyst.

At the SOFC mode, a small amount of hydrogen of the exhaust gas exhausted from the hydrogen pole <NUM> is functioned as a fuel at the catalytic combustor <NUM>, to heat the air exhausted from the air pole <NUM>, and thus the temperature of the exhaust gas of the air pole <NUM> is increased by about <NUM> to <NUM>.

For example, without the catalytic combustor <NUM> as in the first to third example embodiments, the temperature of the exhaust gas exhausted from the air pole <NUM> may be about <NUM>, but with the catalytic combustor <NUM> as in the present example embodiment, the temperature of the exhaust gas passing through the catalytic combustor <NUM> may be heated to a temperature between <NUM> and <NUM>. Accordingly, the exhaust gas is additionally heated and thus more increased thermal energy may be provided to the air of the air passage L53 at the air-exhaust gas heat exchanger <NUM>, so that the second heater <NUM> may not be operated. The specific temperatures mentioned at the above explanation may be examples, and the specific temperature or the specific range of the temperature may be variously changed.

Here, at the SOFC mode at which the air is required, the catalytic combustor <NUM> is used, but at the SOEC mode, the catalytic combustor <NUM> may not be used. Thus, an on-off valve (not shown) may be equipped to the bifurcation passage L46, and the valve may be open at the SOFC mode and closed at the SOEC mode. Alternatively, to avoid using a relatively high temperature valve, the on-off valve may be equipped to the recycling passage L44 after the blower <NUM>, instead of being equipped to the bifurcation passage L46.

<FIG> is a schematic diagram illustrating a reversible water electrolysis system according to a fifth example embodiment of the present invention.

The reversible water electrolysis system according to the present example embodiment is substantially same as the reversible water electrolysis system in <FIG> except that an ejector <NUM> equipped at a steam supply passage L21 and a bifurcation passage L22 bifurcated from the steam supply passage are further included, and the pump <NUM> in <FIG> is omitted in the water discharge passage L43, and thus same references are used for the same elements and any repetitive explanation will be omitted.

Referring to <FIG>, in the reversible water electrolysis system according to the present example embodiment, the steam supply passage L21 includes the bifurcation passage L22. As illustrated in <FIG>, the bifurcation passage L22 is bifurcated from the steam supply passage L21 and interflows to the passage L21 again. An on-off valve <NUM> may be equipped at the bifurcation passage L22, and although not shown in the figure, the on-off valve may be also equipped to the steam supply passage L21. The steam may be controlled to be flowed into one of the steam supply passage L21 and the bifurcation passage L22, by controlling the on-off valve. Alternatively, a <NUM>-way valve may be equipped at a bifurcation point at which the bifurcation passage L22 is formed, to control the flow of the steam.

The ejector <NUM> is equipped at the steam supply passage L21, and is arranged in parallel with the bifurcation passage L22. Here, the steam from the steam generator <NUM> may be transferred to the hydrogen pole <NUM> via the ejector <NUM>, or may be transferred to the hydrogen pole <NUM> via the bifurcation passage L22 with bypassing the ejector <NUM>.

The ejector <NUM> mixes a fluid using Venturi effect, and the fluid to be mixed is injected to a venturi tube having a diameter gradually decreased and expanded.

Normally, an inlet of the ejector <NUM> is called as a motive nozzle, an outlet of the ejector <NUM> is called as a diffuser nozzle, and an injecting port through which the fluid is injected is called as a suction port. In the present example embodiment as illustrated in the figure, the motive nozzle of the ejector <NUM> is connected to an upstream side of the steam supply passage L21, the diffuser nozzle of the ejector <NUM> is connected to a downstream side of the steam supply passage L21, and the suction port of the ejector <NUM> is connected to a feedback passage L47. The feedback passage L47 is bifurcated from the exhaust passage L41 at which the exhaust gas of the hydrogen pole <NUM> flows.

Normally, at the SOEC mode, a volume ratio between the steam and the hydrogen injected to the hydrogen pole <NUM> is about <NUM>:<NUM>. In the exhaust gas exhausted from the hydrogen pole <NUM>, the amount of the hydrogen is relatively large, and thus the hydrogen is unnecessary to be additionally supplied via the hydrogen supply passage L11 if the recycling gas is partially recycled via the feedback passage L47. Here, the ejector <NUM> controls the pressure or the amount of the steam supplied to the motive nozzle (transferred via the passage L21), to control the amount of the exhaust gas recycled to the feedback passage L47.

Hereinafter, referring to <FIG> and <FIG>, the SOEC mode and the SOFC mode of the reversible water electrolysis system according to the fifth example embodiment are explained.

Referring to <FIG>, at the SOEC mode, the steam is supplied via the steam supply passage L21. The outer supply water is supplied via the water supply passage L31 and the outer supply water is evaporated at the second heat exchanger <NUM>, and then the evaporated water interflows to the steam supply passage L21. The mixed steam passes through the ejector <NUM>, and here, the exhaust gas exhausting via the exhaust passage L41 is partially flowed into the ejector <NUM> via the feedback passage L47 to be mixed with the steam. The above mixed gas is supplied to the hydrogen pole <NUM> of the fuel cell <NUM> via the passage L12.

At the SOEC mode, relatively a small amount of air is necessary, and thus the first blower <NUM> is operated to supply the air to the air pole <NUM> of the fuel cell <NUM> and the second blower <NUM> is not operated.

At the SOEC mode, the catalytic combustor <NUM> may not be used, and the first exhaust gas exhausting to the exhaust passage L41 is partially bifurcated at the feedback passage L47 and then is supplied to the suction port of the ejector <NUM>. The remaining exhaust gas passes through the first heat exchanger <NUM> without the heat exchanging, and transmits the thermal energy at the outer supply water at the second heat exchanger <NUM>.

In the present example embodiment, at the SOEC mode, the recycling passage L44 is closed, and thus the exhaust gas of the exhaust passage L41 passes through the third heat exchange <NUM> without the heat exchanging and then is transferred to the water discharger. At the water discharger, the steam is condensed to be discharged to outside via the water discharge passage L43, and the hydrogen and the steam which is not condensed are transferred via the passage L45. Then, the hydrogen and the uncondensed steam are separately treated.

Referring to <FIG>, at the SOFC mode, the hydrogen is supplied via the hydrogen supply passage L11, and a small amount of steam is supplied via the steam supply passage L21. The hydrogen is heat-exchanged with the exhaust gas of the exhaust passage L41 at the first heat exchanger <NUM> to be heated and then is supplied to the hydrogen pole <NUM>. The steam is transferred via the bifurcation passage L22 by bypassing the ejector <NUM>, interflows to the hydrogen, and then is supplied to the hydrogen pole <NUM>.

At the SOFC mode, relatively large amount of air is necessary, so that the second blower <NUM> is operated to supply the air to the air pole <NUM> and the first blower <NUM> is not operated. Alternatively, both of the first and second blowers <NUM> and <NUM> may be operated.

In the present example embodiment, at the SOFC mode, the catalytic combustor <NUM> is operated. The exhaust gas exhausted from the hydrogen pole <NUM> is partially supplied to the catalytic combustor <NUM> via the bifurcation passage L45 to be a fuel of the catalytic combustor <NUM>, and the air exhausted from the air pole <NUM> is heated. The catalytic combustor <NUM> may increase the temperature of the exhaust gas of the air pole <NUM> by about <NUM> to <NUM>. Thus, the additionally heated exhaust gas may transmit the thermal energy to the air of the air passage L53 more at the air-exhaust gas heat exchanger <NUM>, so that the second heater <NUM> may not to be operated.

As the chemical reaction between the hydrogen and the oxygen occurs at the fuel cell <NUM>, the first exhaust gas including the steam and the hydrogen is exhausted from the hydrogen pole <NUM> via the exhaust passage L41, and the second exhaust gas including the nitrogen and the oxygen is exhausted from the air pole <NUM> via the exhaust passage L61.

The first exhaust gas heats the hydrogen with passing through the first heat exchanger <NUM>. At the SOEC mode, since the outer supply water is not supplied, the first exhaust gas passes through the third heat exchanger <NUM> without the heat exchanging, and the first exhaust gas is heat-exchanged with the recycling gas at the second heat exchanger <NUM> to heat the recycling gas. Then, the first exhaust gas is transferred to the water discharger, and the steam is condensed to be discharged via the water discharge passage L43. Here, the hydrogen and the uncondensed steam are resupplied to the hydrogen pole <NUM> via the recycling passage L44 as the recycling gas.

Accordingly, in the present example embodiment, the mixed gas of the hydrogen and the steam is properly supplied to the fuel cell <NUM> according to each of the SOEC mode and the SOFC mode.

For example, at the SOEC mode, relatively a small amount of hydrogen is necessary, and thus the hydrogen included in the exhaust gas fed-back via the feedback passage L47 is used. Thus, the hydrogen is unnecessary to be supplied from outside via the hydrogen supply passage L11. In addition, relatively a small amount of air is also necessary, and thus the first blower <NUM> which is a relatively small size is only operated to supply the air.

In contrast, at the SOFC mode, the exhaust gas is resupplied via the recycling passage L44 not via the feedback passage L47, so that the hydrogen which is not reacted at the fuel cell <NUM> and is wasted is minimized. In addition, the steam is supplied by bypassing the ejector <NUM>, so that the ejector <NUM> is prevented from being interfered, and the second heat exchanger <NUM> is equipped at the upstream side of the blower <NUM> of the recycling passage L44 to prevent the blower <NUM> from being damage.

<FIG> is a schematic diagram illustrating a reversible water electrolysis system according to a sixth example embodiment of the present invention.

The reversible water electrolysis system according to the present example embodiment is substantially same as the reversible water electrolysis systems according to the previous fourth and fifth example embodiments except that the ejector <NUM> and the drain pump <NUM> are included.

Likewise the reversible water electrolysis system according to the previous fifth example embodiment, the ejector <NUM> is equipped at the steam supply passage L21, and the bifurcation passage L22 bypassing the ejector <NUM> is connected to the ejector <NUM> in parallel.

In addition, likewise the reversible water electrolysis system according to the previous fourth example embodiment, the drain pump <NUM> is equipped at the water discharge passage L43, and forces to pump the water discharged via the passage L42 at the drain <NUM> so as to discharge the water to outside.

Here, the effects of the ejector <NUM> and the drain pump <NUM> are explained above in detail, and thus any repetitive explanation will be omitted.

Accordingly, in the reversible water electrolysis system according to the present example embodiment, the mixed gas including the hydrogen and the steam is properly supplied to the fuel cell according to each of the SOEC mode and the SOFC mode, and the waste heat of the exhaust gas exhausted from the fuel cell is also properly reused. Thus, the efficiency of the system may be increased.

Generally, at the SOEC mode of the reversible water electrolysis system, the system efficiency may be defined as below equations. <MAT> <MAT> <MAT>.

In the above equations, η1 is an efficiency defined as a rate between an output energy and an input energy. The input energy which is a denominator means a calorie of a waste supplied to the boiler <NUM> and an electric energy supplied to the fuel cell <NUM> by a renewable energy. The output energy which is a numerator means a calorie of the hydrogen generated at the fuel cell <NUM>, in other words, an amount of the generated hydrogen at the fuel cell <NUM>. η2 means the elimination of the calorie of the waste at the denominator of η1. η3 means an efficiency of exergy, which is the efficiency reflecting both of quantity and quality of the energy.

Likewise, at the SOFC mode of the reversible water electrolysis system, the system efficiency may be defined as below equations. <MAT> <MAT> <MAT>.

According to the above equations, the efficiency of exergy η3 was calculated for each of the first to fourth example embodiments of the present invention at the SOEC mode. Thus, the efficiency of exergy η3 is <NUM>% for the first example embodiment, <NUM>% for the second example embodiment, <NUM>% for the third example embodiment, and <NUM>% for the fourth example embodiment.

The efficiency of exergy η3 is known as between about <NUM>% and about <NUM>% for the conventional reversible water electrolysis system at the SOEC mode. Thus, the system efficiency of the example embodiments of the present invention may be increased compared to the conventional reversible water electrolysis system.

In addition, the efficiency of exergy η3 was calculated for each of the first to fourth example embodiments of the present invention at the SOFC mode. Here, the efficiency of exergy η3 is <NUM>% for each of the first and second example embodiments, but the efficiency of exergy η3 is <NUM>% for the third example embodiment and <NUM>% for the fourth example embodiment. Since the waste energy of the fuel cell is recycled to heat the air supplied to the air pole <NUM> and the power consumption of the second heater <NUM> is decreased in the third and fourth example embodiments, the energy efficiency is more increased in the third and fourth example embodiments, compared to the first and second example embodiments.

Claim 1:
A reversible water electrolysis system comprising:
a reversible water electrolysis fuel cell <NUM> having a hydrogen pole, an air pole and an electrolyte disposed between the hydrogen pole and the air pole, wherein the reversible water electrolysis fuel cell is configured to be operated at one of a water electrolysis mode and a fuel cell mode;
a first heat exchanger <NUM> configured to exchange a heat between a first exhaust gas exhausted from the hydrogen pole and a hydrogen or a mixed gas including the hydrogen and a steam, wherein the hydrogen or the mixed gas is supplied to the hydrogen pole;
a steam supply passage L21 configured to supply the steam to the hydrogen pole;
a water discharger configured to removing a water from the first exhaust gas; and
a pump equipped to a water discharge passage L43 of the water discharge and configured to pump the water to outside,
wherein the pump is configured to maintain a pressure difference between an inlet of the hydrogen pole and an inlet of the air pole within a predetermined range.