(19)
(11)EP 2 922 128 B1

(12)EUROPEAN PATENT SPECIFICATION

(45)Mention of the grant of the patent:
29.04.2020 Bulletin 2020/18

(21)Application number: 15157761.6

(22)Date of filing:  05.03.2015
(51)International Patent Classification (IPC): 
H01M 8/04007(2016.01)
H01M 8/04089(2016.01)
H01M 8/124(2016.01)
H01M 8/0612(2016.01)
H01M 8/04014(2016.01)
H01M 8/0662(2016.01)
H01M 8/2475(2016.01)
H01M 8/0637(2016.01)

(54)

FUEL CELL SYSTEM

BRENNSTOFFZELLENSYSTEM

SYSTÈME DE PILE À COMBUSTIBLE


(84)Designated Contracting States:
AL AT BE BG CH CY CZ DE DK EE ES FI FR GB GR HR HU IE IS IT LI LT LU LV MC MK MT NL NO PL PT RO RS SE SI SK SM TR

(30)Priority: 17.03.2014 JP 2014053260

(43)Date of publication of application:
23.09.2015 Bulletin 2015/39

(73)Proprietor: Panasonic Corporation
Kadoma-shi Osaka 571-8501 (JP)

(72)Inventor:
  • Yakuraru, Yuuichi
    Osaka 540-6207 (JP)

(74)Representative: Grünecker Patent- und Rechtsanwälte PartG mbB 
Leopoldstraße 4
80802 München
80802 München (DE)


(56)References cited: : 
JP-A- 2011 216 308
US-A- 3 655 448
JP-A- 2013 222 573
  
      
    Note: Within nine months from the publication of the mention of the grant of the European patent, any person may give notice to the European Patent Office of opposition to the European patent granted. Notice of opposition shall be filed in a written reasoned statement. It shall not be deemed to have been filed until the opposition fee has been paid. (Art. 99(1) European Patent Convention).


    Description

    BACKGROUND


    1. Technical Field



    [0001] The present disclosure relates to a fuel cell system.

    2. Description of the Related Art



    [0002] A fuel cell system can derive electric energy with high efficiency by way of reaction of hydrogen-containing gas produced by reforming power generation material and oxygen in the air acting as oxidant. Since a catalyst used for reforming the power generation material decreases in activity when poisoned with sulfur, sulfur compounds in the power generation material need to be removed before reformation. Sulfur compounds can be removed by hydro-desulfurization in which hydrogen is mixed with the power generation material, for example.

    [0003] A fuel cell system typically feeds a part of hydrogen-containing gas resulting from reformation of the power generation material back to the power generation material channel as the source of hydrogen to be mixed with the power generation material. For this purpose, a pressure feeder such as a blower may be provided in a recycle channel, or an orifice or the like may be provided upstream of the junction of the power generation material channel and the recycle channel for adjusting pressure balance such that the pressure of hydrogen-containing gas becomes higher than the pressure in the junction.

    [0004] A fuel cell system can encounter the problem of condensed water being fed to a power generation material feeder that feeds power generation material as a result of condensation of water vapor in hydrogen-containing gas from the recycle channel, or the problem of a gas channel being blocked by condensed water.

    [0005] As a solution to these problems, Japanese Unexamined Patent Application Publication No. 2013-222573 proposes a method in which an ejector is provided between the power generation material feeder and the hydro-desulfurizer in a fuel cell system so that hydrogen-containing gas is suctioned into the ejector. This can prevent condensed water in the hydrogen-containing gas flowing in the recycle channel from entering the power generation material feeder. US 3,655,448 A relates to a hydrogen generator desulfurizer employing a feedback ejector. JP 2011 216308 A is about a solid oxide fuel battery system.

    SUMMARY



    [0006] Conventional arts, however, do not sufficiently address the problem of the ejector being blocked by condensed water in hydrogen-containing gas from the recycle channel.

    [0007] One non-limiting and exemplary embodiment provides a fuel cell system that can reduce the possibility of an ejector being blocked by condensed water in hydrogen-containing gas from a recycle channel compared to conventional arts.

    [0008] A fuel cell system according to the present invention is defined in claim 1.

    [0009] The fuel cell system according to the present invention as claimed can reduce the possibility of the ejector being blocked by condensed water in hydrogen-containing gas from the recycle channel compared to conventional arts.

    [0010] Additional benefits and advantages of the disclosed embodiments will become apparent from the specification and drawings. The benefits and/or advantages may be individually obtained by the various embodiments and features of the specification and drawings, which need not all be provided in order to obtain one or more of such benefits and/or advantages. Further advantageous embodiments are defined in the dependent claims.

    BRIEF DESCRIPTION OF THE DRAWINGS



    [0011] 

    Fig. 1 illustrates an example of the fuel cell system according to a first embodiment;

    Fig. 2 illustrates an example of the fuel cell system according to a first variation of the first embodiment;

    Fig. 3 illustrates an example of the fuel cell system according to a second embodiment;

    Fig. 4 illustrates an example of the fuel cell system according to a first variation of the second embodiment;

    Fig. 5 illustrates an example of the fuel cell system according to a third embodiment; and

    Fig. 6 illustrates an example of the fuel cell system according to a fourth embodiment.


    DETAILED DESCRIPTION



    [0012] The present inventor has obtained the following findings after researching into the problem of the ejector being blocked by condensed water in hydrogen-containing gas from the recycle channel.

    [0013] Hydrogen-containing gas flowing in the recycle channel contains water vapor and produces condensed water upon being cooled. For example, when hydrogen-containing gas is cooled by heat dissipation, condensed water is generated from the hydrogen-containing gas. Hydrogen-containing gas also produces condensed water when it is cooled by being mixed with power generation material of a lower temperature than that of the hydrogen-containing gas. Such condensed water can potentially block the ejector.

    [0014] A fuel cell system according to the invention is defined in claim 1.

    [0015] In this arrangement, the amount of condensed water in the ejector can be reduced because the ejector is heated by exhaust gas from the fuel cell unit. Compared to conventional arts, the possibility of the ejector being blocked by condensed water in hydrogen-containing gas from the recycle channel can be reduced.

    [0016] The hydro-desulfurizer may be arranged to be heated by the exhaust gas.

    [0017] In this arrangement, the amount of condensed water in the hydro-desulfurizer can be reduced because the hydro-desulfurizer is heated by exhaust gas, which in turn can reduce the possibility of decrease in performance of the hydro-desulfurization catalyst due to condensed water or the possibility of a channel blockage in the hydro-desulfurizer.

    [0018] According to claim 1, the fuel cell system further includes a first container that houses the fuel cell unit and a second container that houses the ejector, in which the second container has an inlet port through which exhaust gas from the fuel cell unit discharged from the first container enters the second container and an outlet port through which exhaust gas exits the second container, and in which the ejector is heated by the exhaust gas flowing between the inlet port and the outlet port.

    [0019] In this arrangement, since the second container forms a flowing route for exhaust gas between the inlet port and the outlet port, placement of the ejector in the second container facilitates heating of the ejector with exhaust gas. The ejector can therefore be effectively heated.

    [0020] The hydro-desulfurizer may be arranged to be heated by the exhaust gas flowing between the inlet port and the outlet port.

    [0021] In this arrangement, since the second container forms a flowing route for exhaust gas between the inlet port and the outlet port, placement of the hydro-desulfurizer in the second container facilitates heating of the hydro-desulfurizer with exhaust gas. The hydro-desulfurizer can therefore be effectively heated.

    [0022] The hydro-desulfurizer may be arranged upstream with respect to flow of the exhaust gas such that the hydro-desulfurizer is heated by the exhaust gas earlier than the ejector.

    [0023] The temperature appropriate for hydrogenation reaction in the hydro-desulfurizer is higher than the temperature required for decreasing the amount of condensed water in hydrogen-containing gas in the ejector. Thus, by heating the hydro-desulfurizer with exhaust gas earlier than the ejector, the temperature in the hydro-desulfurizer can be appropriately increased while decreasing the amount of condensed water in the ejector.

    [0024] The hydro-desulfurizer may be placed closer to the inlet port than the ejector is.

    [0025] In this arrangement, the temperature appropriate for hydrogenation reaction in the hydro-desulfurizer is higher than the temperature required for decreasing the amount of condensed water in hydrogen-containing gas in the ejector. As exhaust gas of high temperature from the fuel cell unit enters the second container from the inlet port of the second container, placing the hydro-desulfurizer closer to the inlet port of the second container than the ejector is to the inlet port enables the temperature in the hydro-desulfurizer to be appropriately increased while decreasing the amount of condensed water in the ejector.

    [0026] The fuel cell unit may include solid oxide fuel cells, a combustor that combusts anode off-gas discharged from the solid oxide fuel cells, and a casing that houses the solid oxide fuel cells and the combustor.

    [0027] The first container and the second container may be rectangular parallelepipeds and may be disposed adjacent to each other, and in which the recycle channel may extend from the first container into the second container via adjacent surfaces of the first container and the second container.

    [0028] In this arrangement, since the recycle channel extends from the first container into the second container with little contact with outside air, heat dissipation in the recycle channel is suppressed, which in turn reduces water condensation in the recycle channel.

    (First Embodiment)


    [Device Structure]



    [0029] Fig. 1 illustrates an example of the fuel cell system in the first embodiment.

    [0030] As illustrated in Fig. 1, a fuel cell system 100 in this embodiment includes a power generation material feeder 1, an ejector 2, a hydro-desulfurizer 3, a fuel cell unit 4, and a recycle channel 5.

    [0031] The power generation material feeder 1 delivers power generation material. For example, for delivery of power generation material, the power generation material feeder 1 is used to increase the pressure of the power generation material. The power generation material feeder 1 may be any mechanism that can deliver power generation material. The power generation material feeder 1 may be a blower or a diaphragm pump, for example. The power generation material contains an organic compound composed at least of carbon and hydrogen. The power generation material may be town gas, natural gas, LP gas, or vaporized liquid fuel such as alcohol, kerosene, and gasoline, for instance. The power generation material is supplied from a power generation material source. The power generation material source has a certain supply pressure, and may be a power generation material cylinder or power generation material infrastructure, for example.

    [0032] The hydro-desulfurizer 3 removes sulfur compounds in the power generation material. The hydro-desulfurizer 3 is formed of a container filled with hydro-desulfurizing agent. The hydro-desulfurizing agent may be a Cu-Zn catalyst that has both the function of converting sulfur compounds to hydrogen sulfide and the function of absorbing hydrogen sulfide, for example. The hydro-desulfurizing agent is not limited to this example; it may be composed of a Co-Mo catalyst that converts sulfur compounds in the power generation material gas to hydrogen sulfide and a ZnO catalyst or Cu-Zn catalyst provided downstream of it as a sulfur absorbent for absorbing and removing hydrogen sulfide.

    [0033] The fuel cell unit 4 generates electric power using the power generation material. The fuel cell unit 4 includes at least fuel cells and may optionally include a reformer for generating hydrogen-containing gas through reforming reaction using the power generation material. When the fuel cell unit 4 does not include a reformer, hydrogen-containing gas is produced in the fuel cells through reforming reaction. An example of this type of fuel cell is an internal reforming solid oxide fuel cell.

    [0034] Reforming reaction in the fuel cell unit 4 may be of any type, such as steam reforming reaction, autothermal reaction, and partial oxidation reaction, for example. Although not shown in Fig. 1, devices necessary for the type of reforming reaction being used are provided. For example, in the case of steam reforming reaction, an evaporator for generating water vapor, a water feeder for supplying water to the evaporator, and the like are provided. In the case of autothermal reaction, an air supply for supplying air is additionally provided. The fuel cells in the fuel cell unit 4 may be of any type, such as polymer electrolyte fuel cells, solid oxide fuel cells, and phosphoric acid fuel cells, for example.

    [0035] The recycle channel 5 supplies a part of the hydrogen-containing gas from the fuel cell unit 4 to the ejector 2. By routing a part of hydrogen-containing gas to the recycle channel 5, hydrogen necessary for hydrogenation reaction in the hydro-desulfurizer 3 can be supplied.

    [0036] The recycle channel 5 may be in any form that enables supply of a part of hydrogen-containing gas from the fuel cell unit 4 to the ejector 2. Hydrogen-containing gas to be supplied to the ejector 2 may be anode off-gas from the fuel cells of the fuel cell unit 4, or if the fuel cell unit 4 includes a reformer, reformed gas from any portion of the gas channel downstream of the reformer, for example, reformed gas downstream of the reformer, reformed gas downstream of a transformer, reformed gas downstream of a CO removal unit, or anode off-gas from the fuel cells.

    [0037] The ejector 2 is provided downstream of the power generation material feeder 1. The ejector 2 increases the velocity of flow of the power generation material from the power generation material feeder 1 to thereby make the pressure in the power generation material channel in the ejector 2 lower than the pressure at the upstream end of the recycle channel 5 so that the hydrogen-containing gas flowing in the recycle channel 5 is drawn into the ejector 2. For example, the ejector 2 may have a throttle mechanism for decreasing the cross-sectional area of the power generation material channel so as to increase the velocity of flow of the power generation material.

    [0038] The ejector 2 is also arranged to be heated by exhaust gas from the fuel cell unit 4. Exhaust gas flows through an exhaust gas channel 6. Exhaust gas from the fuel cell unit 4 for heating the ejector 2 may be anode off-gas or cathode off-gas from the fuel cells of the fuel cell unit 4, for example. If the fuel cell unit 4 includes a combustor for combusting anode off-gas, combustion exhaust gas from the combustor may be used as the exhaust gas for heating the ejector 2.

    [0039] As noted above, hydrogen-containing gas flowing in the recycle channel 5 contains water vapor and produces condensed water upon being cooled. For example, when hydrogen-containing gas is cooled by heat dissipation, condensed water is generated from the hydrogen-containing gas. Hydrogen-containing gas also produces condensed water when it is cooled by being mixed with power generation material of a lower temperature than that of the hydrogen-containing gas. Such condensed water can potentially block the ejector 2.

    [0040] By heating the ejector 2 with exhaust gas from the fuel cell unit 4, this embodiment can decrease the amount of condensed water in the ejector 2. Thus, the possibility of the ejector 2 being blocked by condensed water in hydrogen-containing gas from the recycle channel 5 can be reduced compared to conventional arts.

    [0041] Although not shown, the fuel cell system 100 may be equipped with valves and the like for shutting off the power generation material channel or the recycle channel 5 or adjusting the flow rate in the channels as necessary. Also, the ejector 2 may be arranged to be heated by a heating element such as an electrical component or solenoid valve.

    (First Variation)


    [Device Structure]



    [0042] Fig. 2 illustrates an example of the fuel cell system in a first variation of the first embodiment.

    [0043] As illustrated in Fig. 2, the fuel cell system 100 in this variation includes the power generation material feeder 1, the ejector 2, a hydro-desulfurizer 3A, the fuel cell unit 4, and the recycle channel 5. As the power generation material feeder 1, the ejector 2, the fuel cell unit 4, and the recycle channel 5 are similar to the first embodiment, descriptions of them are omitted.

    [0044] The hydro-desulfurizer 3A is arranged to be heated by exhaust gas from the fuel cell unit 4.

    [0045] By heating the hydro-desulfurizer 3A with exhaust gas, the amount of condensed water in the hydro-desulfurizer 3A can be decreased. This can in turn reduce the possibility of decrease in performance of the hydro-desulfurization catalyst due to condensed water or the possibility of a channel blockage in the hydro-desulfurizer 3A.

    (Second Variation)


    [Device Structure]



    [0046] The fuel cell system 100 in this variation has a similar structure to Fig. 2; it includes the power generation material feeder 1, the ejector 2, the hydro-desulfurizer 3A, the fuel cell unit 4, and the recycle channel 5. As the power generation material feeder 1, the ejector 2, the fuel cell unit 4, and the recycle channel 5 are similar to the first embodiment, descriptions of them are omitted.

    [0047] The hydro-desulfurizer 3A is arranged to be heated by exhaust gas earlier than the ejector 2.

    [0048] The temperature appropriate for hydrogenation reaction in the hydro-desulfurizer 3A is higher than the temperature required for decreasing the amount of condensed water in hydrogen-containing gas in the ejector 2. For example, when a Cu-Zn catalyst is used as the hydro-desulfurizing agent, the temperature range for effective operation of the hydro-desulfurizer 3A is about 150°C to 350°C. Thus, by heating the hydro-desulfurizer 3A with exhaust gas earlier than the ejector 2, the temperature in the hydro-desulfurizer 3A can be appropriately increased while decreasing the amount of condensed water in the ejector 2.

    (Second Embodiment)


    [Device Structure]



    [0049] Fig. 3 illustrates an example of the fuel cell system in a second embodiment.

    [0050] As illustrated in Fig. 3, the fuel cell system 100 in this embodiment includes the power generation material feeder 1, the ejector 2, the hydro-desulfurizer 3, the fuel cell unit 4, the recycle channel 5, a first container 7, a second container 8, an inlet port 9, and an outlet port 10. As the power generation material feeder 1, the ejector 2, the hydro-desulfurizer 3, the fuel cell unit 4, and the recycle channel 5 are similar to the first embodiment, descriptions of them are omitted.

    [0051] The first container 7 houses the fuel cell unit 4. In this embodiment, the fuel cell unit 4 and the hydro-desulfurizer 3 are disposed inside the first container 7.

    [0052] The second container 8 houses the ejector 2. The second container 8 has the inlet port 9 through which exhaust gas from the fuel cell unit 4 discharged from the first container 7 enters the second container 8 and the outlet port 10 through which exhaust gas exits the second container 8, and the ejector 2 is arranged to be heated by the exhaust gas flowing between the inlet port 9 and the outlet port 10. The path on which exhaust gas flows between the inlet port 9 and the outlet port 10 forms a part of the exhaust gas channel 6.

    [0053] As described above, since the second container 8 forms a flowing route for exhaust gas between the inlet port 9 and the outlet port 10, placement of the ejector 2 in the second container 8 facilitates heating of the ejector 2 with exhaust gas. The ejector 2 can therefore be effectively heated.

    (First Variation)


    [Device Structure]



    [0054] Fig. 4 illustrates an example of the fuel cell system in a first variation of the second embodiment.

    [0055] As illustrated in Fig. 4, the fuel cell system 100 in this variation includes the power generation material feeder 1, the ejector 2, the hydro-desulfurizer 3A, the fuel cell unit 4, the recycle channel 5, the first container 7, the second container 8, the inlet port 9, and the outlet port 10. As the power generation material feeder 1, the ejector 2, the fuel cell unit 4, the recycle channel 5, the first container 7, the second container 8, the inlet port 9, and the outlet port 10 are similar to the second embodiment, descriptions of them are omitted.

    [0056] The hydro-desulfurizer 3A is heated by the exhaust gas flowing between the inlet port 9 and the outlet port 10 of the second container 8.

    [0057] In this variation, the ejector 2 and the hydro-desulfurizer 3A are disposed inside the second container 8.

    [0058] As described above, since the second container 8 forms a flowing route for exhaust gas between the inlet port 9 and the outlet port 10, placement of the hydro-desulfurizer 3A in the second container 8 facilitates heating of the hydro-desulfurizer 3A with exhaust gas. The hydro-desulfurizer 3A can therefore be effectively heated.

    (Second Variation)


    [Device Structure]



    [0059] The fuel cell system 100 in this variation has a similar structure to Fig. 4; it includes the power generation material feeder 1, the ejector 2, the hydro-desulfurizer 3A, the fuel cell unit 4, the recycle channel 5, the first container 7, the second container 8, the inlet port 9, and the outlet port 10. As the power generation material feeder 1, the ejector 2, the fuel cell unit 4, the recycle channel 5, the first container 7, the second container 8, the inlet port 9, and the outlet port 10 are similar to the second embodiment, descriptions of them are omitted.

    [0060] The hydro-desulfurizer 3A is arranged to be heated by exhaust gas earlier than the ejector 2.

    [0061] The temperature appropriate for hydrogenation reaction in the hydro-desulfurizer 3A is higher than the temperature required for decreasing the amount of condensed water in hydrogen-containing gas in the ejector 2. For example, when a Cu-Zn catalyst is used as the hydro-desulfurizing agent, the temperature range for effective operation of the hydro-desulfurizer 3A is about 150°C to 350°C.

    [0062] Thus, by heating the hydro-desulfurizer 3A with exhaust gas earlier than the ejector 2, the temperature in the hydro-desulfurizer 3A can be appropriately increased while decreasing the amount of condensed water in the ejector 2.

    (Third Variation)


    [Device Structure]



    [0063] The fuel cell system 100 in this variation has a similar structure to Fig. 4; it includes the power generation material feeder 1, the ejector 2, the hydro-desulfurizer 3A, the fuel cell unit 4, the recycle channel 5, the first container 7, the second container 8, the inlet port 9, and the outlet port 10. As the power generation material feeder 1, the ejector 2, the fuel cell unit 4, the recycle channel 5, the first container 7, the second container 8, the inlet port 9, and the outlet port 10 are similar to the second embodiment, descriptions of them are omitted.

    [0064] The hydro-desulfurizer 3A is placed closer to the inlet port 9 of the second container 8 than the ejector 2 is.

    [0065] The temperature appropriate for hydrogenation reaction in the hydro-desulfurizer 3A is higher than the temperature required for decreasing the amount of condensed water in hydrogen-containing gas in the ejector 2. For example, when a Cu-Zn catalyst is used as the hydro-desulfurizing agent, the temperature range for effective operation of the hydro-desulfurizer 3A is about 150°C to 350°C.

    [0066] As exhaust gas of high temperature from the fuel cell unit 4 enters the second container 8 from the inlet port 9 of the second container 8, by placing the hydro-desulfurizer 3A closer to the inlet port 9 of the second container 8 than the ejector 2 is, the temperature in the hydro-desulfurizer 3A can be appropriately increased while decreasing the amount of condensed water in the ejector 2.

    (Third Embodiment)


    [Device Structure]



    [0067] Fig. 5 illustrates an example of the fuel cell system in a third embodiment.

    [0068] As illustrated in Fig. 5, the fuel cell system 100 in this embodiment includes the power generation material feeder 1, the ejector 2, the hydro-desulfurizer 3A, the fuel cell unit 4, the recycle channel 5, the first container 7, the second container 8, the inlet port 9, and the outlet port 10. As the power generation material feeder 1, the ejector 2, the fuel cell unit 4, the recycle channel 5, the first container 7, the second container 8, the inlet port 9, and the outlet port 10 are similar to the first variation of the second embodiment, descriptions of them are omitted.

    [0069] The fuel cell unit 4 includes solid oxide fuel cells 11 and a combustion unit 12 that combusts anode off-gas discharged from the solid oxide fuel cells 11. The solid oxide fuel cells 11 and the combustion unit 12 are housed in a casing (not shown). The casing is covered by the first container 7. A heat dissipation inhibiting component for suppressing heat dissipation from the casing may be provided between the casing and the first container 7. The heat dissipation inhibiting component may be heat insulating material, for example.

    [0070] Except for the foregoing, the fuel cell system in this embodiment may have a similar structure to the fuel cell system in any of the first embodiment, the first and second variations of the first embodiment, the second embodiment, and the first to third variations of the second embodiment.

    (Fourth Embodiment)


    [Device Structure]



    [0071] Fig. 6 illustrates an example of the fuel cell system in the fourth embodiment.

    [0072] As illustrated in Fig. 6, the fuel cell system in this embodiment includes the power generation material feeder 1, the ejector 2, the hydro-desulfurizer 3A, the fuel cell unit 4, the recycle channel 5, the first container 7, the second container 8, the inlet port 9, the outlet port 10, the solid oxide fuel cells 11, and the combustion unit 12. As the power generation material feeder 1, the ejector 2, the fuel cell unit 4, recycle channel 5, the first container 7, the second container 8, the inlet port 9, the outlet port 10, the solid oxide fuel cells 11, and the combustion unit 12 are similar to the third embodiment, descriptions of them are omitted.

    [0073] The first container 7 and the second container 8 are rectangular parallelepipeds and disposed adjacent to each other. The recycle channel 5 extends from the first container 7 into the second container 8 via the adjacent surfaces of the first container 7 and the second container 8.

    [0074] Except for the foregoing, the fuel cell system in this embodiment may have a similar structure to the fuel cell system in any of the first embodiment, the first and second variations of the first embodiment, the second embodiment, the first to third variations of the second embodiment, and the third embodiment.

    [0075] An aspect of the present disclosure can reduce the possibility of the ejector being blocked by condensed water in hydrogen-containing gas from the recycle channel compared to conventional arts. Thus, an aspect of the present disclosure is applicable to a fuel cell system, for example.


    Claims

    1. A fuel cell system comprising:

    a hydro-desulfurizer (3) configured to remove sulfur compounds in power generation material;

    a fuel cell unit (4) configured to generate electric power using the power generation material and discharge exhaust gas;

    a recycle channel (5) configured to supply a part of hydrogen-containing gas from the fuel cell unit (4) to a power generation material channel before the power generation material enters the hydro-desulfurizer (3); and

    an ejector (2) which is provided in the power generation material channel upstream of the hydro-desulfurizer (3) and into which the hydrogen-containing gas from the recycle channel (5) flows,

    characterized in that

    the fuel cell system further comprising:

    a first container (7) that houses the fuel cell unit (4); and

    a second container (8) that houses the ejector (2),

    wherein the second container (8) has an inlet port (9) through which the exhaust gas from the fuel cell unit (4) discharged from the first container (7) enters the second container (8) and an outlet port (10) through which exhaust gas exits the second container (8), and

    the ejector (2) is arranged to be heated by the exhaust gas flowing between the inlet port (9) and the outlet port (10).


     
    2. The fuel cell system according to Claim 1, wherein the hydro-desulfurizer (3) is arranged to be heated by the exhaust gas from the fuel cell unit (4).
     
    3. The fuel cell system according to Claim 1, wherein the hydro-desulfurizer (3) is arranged to be heated by the exhaust gas flowing between the inlet port (9) and the outlet port (10).
     
    4. The fuel cell system according to Claim 2, wherein the hydro-desulfurizer (3) is arranged upstream with respect to the flow of the exhaust gas such that the hydro-desulfurizer (3) is heated by the exhaust gas earlier than the ejector (2).
     
    5. The fuel cell system according to Claim 3, wherein the hydro-desulfurizer (3) is placed closer to the inlet port (9) than the ejector (2) is.
     
    6. The fuel cell system according to Claim 1, wherein the fuel cell unit (4) includes solid oxide fuel cells (11), a combustor (12) configured to combust anode off-gas discharged from the solid oxide fuel cells (11), and a casing (4) that houses the solid oxide fuel cells (11) and the combustor (12).
     
    7. The fuel cell system according to Claim 1,
    wherein the first container (7) and the second container (8) are rectangular parallelepipeds and disposed adjacent to each other, and
    wherein the recycle channel (5) extends from the first container (7) into the second container (8) via adjacent surfaces of the first container (7) and the second container (8).
     


    Ansprüche

    1. Brennstoffzellen-System, das umfasst:

    eine Hydro-Entschwefelungseinrichtung (3), die so eingerichtet ist, dass sie Schwefelverbindungen aus einem Energieerzeugungs-Material entfernt;

    eine Brennstoffzellen-Einheit (4), die so eingerichtet ist, dass sie elektrische Energie unter Verwendung des Energieerzeugungs-Materials erzeugt und Abgas ableitet;

    einen Rückführungs-Kanal (5), der so eingerichtet ist, dass er einen Teil wasserstoffhaltigen Gases von der Brennstoffzellen-Einheit (4) einem Kanal für Energieerzeugungs-Material zuführt, bevor das Energieerzeugungs-Material in die Hydro-Entschwefelungseinrichtung (3) gelangt; sowie

    einen Ejektor (2), der in dem Kanal für Energieerzeugungs-Material stromauf von der Hydro-Entschwefelungseinrichtung (3) angeordnet ist und in den das wasserstoffhaltige Gas aus dem Rückführungs-Kanal (5) strömt,

    dadurch gekennzeichnet, dass

    das Brennstoffzellen-System (100) des Weiteren umfasst:

    einen ersten Behälter (7), der die Brennstoffzellen-Einheit (4) aufnimmt; sowie

    einen zweiten Behälter (8), der den Ejektor (2) aufnimmt,

    wobei der zweite Behälter (8) einen Einlass-Anschluss (9), über den das Abgas von der Brennstoffzellen-Einheit (4), das aus dem ersten Behälter (7) abgeleitet wird, in den zweiten Behälter (8) gelangt, sowie einen Auslass-Anschluss (10) aufweist, über den das Abgas aus dem zweiten Behälter (8) austritt, und

    der Ejektor (2) so eingerichtet ist, dass er durch das Abgas erwärmt wird, das zwischen dem Einlass-Anschluss (9) und dem Auslass-Anschluss (10) strömt.


     
    2. Brennstoffzellen-System nach Anspruch 1, wobei die Hydro-Entschwefelungseinrichtung (3) so eingerichtet ist, dass sie durch das Abgas von der Brennstoffzellen-Einheit (4) erwärmt wird.
     
    3. Brennstoffzellen-System nach Anspruch 1, wobei die Hydro-Entschwefelungseinrichtung (3) so eingerichtet ist, dass sie durch das Abgas erwärmt wird, das zwischen dem Einlass-Anschluss (9) und dem Auslass-Anschluss (10) strömt.
     
    4. Brennstoffzellen-System nach Anspruch 2, wobei die Hydro-Entschwefelungseinrichtung (3) in Bezug auf den Strom des Abgases stromauf angeordnet ist, so dass die Hydro-Entschwefelungseinrichtung (3) durch das Abgas früher erwärmt wird als der Ejektor (2).
     
    5. Brennstoffzellen-System nach Anspruch 3, wobei die Hydro-Entschwefelungseinrichtung (3) näher an dem Einlass-Anschluss (9) positioniert ist als der Ejektor (2).
     
    6. Brennstoffzellen-System nach Anspruch 1, wobei die Brennstoffzellen-Einheit (4) Festoxid-Brennstoffzellen (11), einen Brenner (12), der so eingerichtet ist, dass er aus den Festoxid-Brennstoffzellen (11) abgeleitetes Anoden-Abgas verbrennt, sowie ein Gehäuse (4) umfasst, das die Festoxid-Brennstoffzellen (11) und den Brenner (12) aufnimmt.
     
    7. Brennstoffzellen-System nach Anspruch 1,
    wobei der erste Behälter (7) und der zweite Behälter (8) Quader sind und benachbart zueinander angeordnet sind, und
    der Rückführungs-Kanal (5) sich von dem ersten Behälter (7) über aneinandergrenzende Flächen des ersten Behälters (7) und des zweiten Behälters (8) in den zweiten Behälter (8) hinein erstreckt.
     


    Revendications

    1. Système de pile à combustible comprenant :

    un hydrodésulfureur (3) configuré pour éliminer des composés soufrés dans un matériau de génération d'énergie ;

    une unité de pile à combustible (4) configurée pour générer de l'énergie électrique en utilisant le matériau de génération d'énergie et décharger un gaz d'échappement ;

    un canal de recyclage (5) configuré pour alimenter une partie du gaz contenant de l'hydrogène provenant de l'unité de pile à combustible (4) à un canal de matériau de génération d'énergie avant que le matériau de génération d'énergie n'entre dans l'hydrodésulfureur (3) ; et

    un éjecteur (2) qui est pourvu dans le canal de matériau de génération d'énergie en amont de l'hydrodésulfureur (3) et dans lequel s'écoule le gaz contenant de l'hydrogène provenant du canal de recyclage (5),

    caractérisé en ce que

    le système de pile à combustible comprend en outre :

    une première enceinte (7) qui reçoit l'unité de pile à combustible (4) ; et

    une deuxième enceinte (8) qui reçoit l'éjecteur (2),

    dans lequel la deuxième enceinte (8) comporte un orifice d'entrée (9) à travers lequel le gaz d'échappement provenant de l'unité de pile à combustible (4) déchargé depuis la première enceinte (7) entre dans la deuxième enceinte (8), et un orifice de sortie (10) à travers lequel le gaz d'échappement sort de la deuxième enceinte (8), et

    l'éjecteur (2) est agencé pour être chauffé par le gaz d'échappement qui s'écoule entre l'orifice d'entrée (9) et l'orifice de sortie (10).


     
    2. Système de pile à combustible selon la revendication 1, dans lequel l'hydrodésulfureur (3) est agencé pour être chauffé par le gaz d'échappement provenant de l'unité de pile à combustible (4).
     
    3. Système de pile à combustible selon la revendication 1, dans lequel l'hydrodésulfureur (3) est agencé pour être chauffé par le gaz d'échappement qui s'écoule entre l'orifice d'entrée (9) et l'orifice de sortie (10).
     
    4. Système de pile à combustible selon la revendication 2, dans lequel l'hydrodésulfureur (3) est agencé en amont du flux de gaz d'échappement, de telle sorte que l'hydrodésulfureur (3) est chauffé par le gaz d'échappement plus tôt que l'éjecteur (2).
     
    5. Système de pile à combustible selon la revendication 3, dans lequel l'hydrodésulfureur (3) est placé plus près de l'orifice d'entrée (9) que l'éjecteur (2).
     
    6. Système de pile à combustible selon la revendication 1, dans lequel l'unité de pile à combustible (4) comprend des piles à combustible à oxyde solide (11), une chambre de combustion (12) configurée pour brûler un effluent gazeux d'anode déchargé par les piles à combustible à oxyde solide (11), et un boîtier (4) qui loge les piles à combustible à oxyde solide (11) et la chambre de combustion (12).
     
    7. Système de pile à combustible selon la revendication 1,
    dans lequel la première enceinte (7) et la deuxième enceinte (8) sont des parallélépipèdes rectangles adjacents entre eux, et
    dans lequel le canal de recyclage (5) s'étend depuis la première enceinte (7) dans la deuxième enceinte (8) via des surfaces adjacentes de la première enceinte (7) et de la deuxième enceinte (8).
     




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    Cited references

    REFERENCES CITED IN THE DESCRIPTION



    This list of references cited by the applicant is for the reader's convenience only. It does not form part of the European patent document. Even though great care has been taken in compiling the references, errors or omissions cannot be excluded and the EPO disclaims all liability in this regard.

    Patent documents cited in the description