JP2009104814A - Fuel cell power generation system - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a fuel cell power generation system equipped with a water treatment system excellent in reliability capable of quickly purifying quality of battery cooling water even at startup of the system. <P>SOLUTION: A circulation line of the battery cooling water is branched to provide a line 18a passed to a water quality purifying device 33 filling ion exchange resin or the like and a line 18b passed to a decarbonator 19, and a shutoff valve 39, 40 is installed at each line, and at the same time, a temperature sensor 38 is installed at an upstream of the water quality purifying device 33. Then, after startup of the fuel cell generation system, the first shutoff valve 40 set at the line 18a passed to the water quality purifying device 33 is structured to be opened to pass the battery cooling water to the water quality purifying device 33, until a detected value of the temperature sensor 38 reaches a given value. On the other hand, if the detected value of the temperature sensor 38 goes beyond the given value, the second shutoff valve 39 set at the line 18b passed to the decarbonator 19 is structured to be opened to pass the battery cooling water to the decarbonator 19. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to a fuel cell power generation system, and more particularly to a fuel cell power generation system improved to improve the performance of a water treatment system for treating battery cooling water or the like.

  The fuel cell power generation system takes out electricity directly by electrochemically reacting hydrogen, which is fuel, and oxygen, which is oxidant, and can take out electric energy with high efficiency, and at the same time, it is quiet and harmful. It is a system with excellent environmental characteristics that does not emit exhaust gas. Recently, development of small PEFC (solid polymer fuel cell) has been activated, and the popularization of household fuel cell power generation systems has become imminent.

  This relatively small fuel cell power generation system for home use or small-scale business is used as a combined heat and power supply so-called cogeneration device that supplies electric power and exhaust heat accompanying power generation.

  Currently, development is proceeding mainly on fuel cell power generation systems that generate electricity using hydrogen obtained from reforming reaction with steam from hydrocarbon fuels such as city gas, LP gas, and kerosene, which already have a fuel supply base. Every day, efforts are made to improve power generation efficiency, quality, and cost.

  Among them, the water treatment system of the fuel cell power generation system is for supplying battery cooling water for maintaining the fuel cell that has generated heat due to the chemical reaction at a normal operating temperature, and for steam reforming the hydrocarbon fuel. Fuel cell power generation by reducing or eliminating makeup water from outside the system by supplying reformed water and collecting condensed water obtained by cooling the gas that is finally discharged to the atmosphere It is one of the important components that are required to improve the efficiency of the system.

  In this water treatment system, the battery cooling water system is generally a circulation system in which cooling water is supplied to the fuel cell by a circulation pump, and the cooling water that has passed through the fuel cell is cooled by a heat exchanger and then returned to the tank. . When the conductivity of the cooling water increases, the cooling water is short-circuited in the fuel cell to cause a decrease in the amount of power generation, and further, the power generation may be stopped.

  In the case of a fuel cell power generation system that uses hydrogen-rich gas obtained by steam reforming a hydrocarbon-based fuel as a fuel, the above-described factors for increasing the electrical conductivity in water include several tens of carbon dioxide at the fuel cell fuel electrode. % Of carbon dioxide produced by melting into the cooling water when it comes into contact with the battery cooling water, carbon dioxide contained in the condensed water obtained by cooling the reformer combustion exhaust gas containing carbon dioxide, Ammonia produced by the gasifier and other ionic components from all equipment, piping and containers in contact with gas and water in the system.

In view of this, various proposals have conventionally been made to reduce the above-described conductivity in water. For example, Patent Document 1 discloses a technique of providing a conductivity reducing device filled with an ion exchange resin or the like. In Patent Document 2, condensed water obtained by cooling the reformer combustion exhaust gas is purified by using the conductivity reducing device as described above, and then reused as battery cooling water or reforming water. A water treatment system is disclosed.
JP 2005-129334 A JP 2007-188847 A

  By the way, in the water treatment system used in the conventional fuel cell power generation system as described above, the amount of treated water takes into account impurities such as ionic components eluted into water during power generation and the generation rate thereof. The fuel cell power generation system has a minimum amount of treated water that can maintain a stable water quality. This is because as the amount of treated water increases, the water purification device becomes larger and the life is shortened.

  However, as described above, when the amount of treated water in the water treatment system is minimized in accordance with the impurity generation speed during power generation operation, it takes time to remove impurities generated during operation stop when starting the fuel cell power generation system. In addition, since the battery cooling water is circulated with insufficient water quality purification, stable operation of the fuel cell power generation system has been difficult.

  The present invention has been proposed to solve the above-described problems of the prior art, and its purpose is to quickly purify the quality of the battery cooling water even when the fuel cell power generation system is started. An object of the present invention is to provide a fuel cell power generation system equipped with a water treatment system with excellent reliability.

  In order to achieve the above object, the invention described in claim 1 is a fuel reforming system that uses a hydrocarbon-based fuel as a raw fuel and produces a hydrogen-rich gas by a steam reforming reaction, and is manufactured by the fuel reforming system. A fuel cell main body that generates electricity using hydrogen-rich gas as fuel and oxygen in the air as oxidant, and battery cooling water for maintaining the fuel cell at an operating temperature from the water tank through the fuel cell to the water tank. In the fuel cell power generation system including the first water circulation system that returns to the water tank and the second water circulation system that returns from the water tank to the water tank through the water purification device, the first water circulation system includes the water purification device. The first branch line connected to the water tank and the second branch line returning to the water tank, and switching means for switching both branch lines are provided to start the fuel cell power generation system. Until the predetermined time is reached, the switching means is switched to the first branch line side, the battery cooling water exiting the fuel cell is passed through the water purification device, and after the predetermined time has elapsed, the switching means Is switched to the second branch line side so that the battery cooling water exiting the fuel cell is returned to the water tank.

  According to the invention of claim 1 having the above-described configuration, after the fuel cell power generation system is started, after the battery cooling water exiting the fuel cell body is introduced into the water purification device and purified for a predetermined time, It is circulated and supplied to the fuel cell main body again through the water tank. On the other hand, after a predetermined time has elapsed since the start of the fuel cell power generation system, the battery cooling water exiting the fuel cell body is returned to the water tank and then circulated and supplied to the fuel cell body again.

  As a result, it becomes possible to quickly and efficiently remove impurities generated during the stoppage of the fuel cell power generation system and accumulated in the battery cooling water when the system is started up, and the amount of treated water during the power generation operation is small. Therefore, the water purification device can be downsized.

  In addition, in order to introduce the battery cooling water into the water purification device for a predetermined time after the start of the fuel cell power generation system, a temperature detection means is provided on the upstream side of the water purification device, and the predetermined time is taken as the fuel cell power generation system. The time until the detection value of the temperature detection means reaches a predetermined temperature after the activation is started.

  In this case, after the start of the fuel cell power generation system, until the detected value of the temperature detecting means reaches a predetermined temperature, the battery cooling water exiting the fuel cell main body is introduced into the water purification device and purified. Then, it is circulated and supplied to the fuel cell main body again through the water tank. On the other hand, when the detected value of the temperature detecting means is equal to or higher than a predetermined temperature, the battery cooling water exiting the fuel cell body is returned to the water tank and then circulated and supplied to the fuel cell body again.

  According to the present invention, it is possible to provide a fuel cell power generation system including a highly reliable water treatment system that can quickly purify the quality of battery cooling water even when the fuel cell power generation system is activated. .

  Hereinafter, embodiments of a fuel cell power generation system according to the present invention will be described with reference to the drawings.

(1) 1st Embodiment 1st Embodiment is described using FIG. In this first embodiment, a circulation line for battery cooling water is branched to provide a line for passage to a water purification device filled with ion exchange resin and the like and a line for passage to a decarbonation tower, and a shutoff valve is provided in each line. At the same time, a temperature detector is installed upstream of the water purification device. Then, after the system is started, until the detection value of the temperature detector reaches a predetermined temperature, the shut-off valve installed in the line passing through the water purification device is opened, and the battery cooling water is passed through the water purification device. It is characterized by that. Hereinafter, this embodiment will be described in detail.

That is, in the present embodiment, the hydrocarbon fuel F is supplied to the fuel cell package 1 from a storage facility such as a pipeline or a gas cylinder. In the fuel cell package 1, the supplied fuel F is desulfurized in the fuel reforming system 2, and then mixed with the vaporized reforming water 3, so that the steam reforming reaction, carbon monoxide (CO) conversion reaction, and CO It is converted into a hydrogen-rich reformed gas 4 containing methane, CO, carbon dioxide (CO ₂ ) or the like whose CO concentration is reduced below the limit value of the battery by a selective oxidation reaction or the like.

  The reformed gas 4 is introduced into the anode 5 a of the fuel cell body 5, and the hydrogen is consumed by power generation together with oxygen in the atmosphere supplied to the fuel cell body 5 cathode 5 b by the air blower 6. The anode exhaust gas 7 that has not been consumed by the anode 5a of the fuel cell body 5 is cooled by the heat exchanger 8 by heat exchange with the exhaust heat recovery circulating water 10 introduced from the hot water tank 9, and the anode exhaust gas condensed water 11 is removed. After that, the fuel is introduced into the fuel inlet of the reformer burner 12, burned in the atmosphere (not shown) supplied from the outside of the fuel cell package 1, and used as a heat source for the steam reforming reaction.

  The anode exhaust gas condensed water 11 generated by the heat exchanger 8 is sent to the condensed water tank 14 of the composite heat exchanger 13. Further, the combustion exhaust gas 15 from the reformer burner 12 is sent to the composite heat exchanger 13, where it is cooled together with the cathode exhaust gas 17 by the heat exchanger 16 to remove condensed water, and then discharged to the atmosphere.

  On the other hand, the cathode exhaust gas 17 in which the oxygen concentration of the cathode 5b of the fuel cell main body 5 is consumed and the oxygen concentration is reduced from the atmosphere is led to the decarbonation tower 19 together with the battery outlet water of the battery cooling water 18, and the battery cooling water 18 After the carbon dioxide gas is reduced, the carbon dioxide gas is sent to the composite heat exchanger 13, and is cooled by the heat exchanger 16 together with the combustion exhaust gas 15 to remove condensed water, and then discharged to the atmosphere.

  In this decarbonation tower 19, a porous structure called a terralet (trade name) made of a heat-resistant resin such as polypropylene or a metal such as a carbon steel stainless steel, or a plurality of flat plates is in contact with water and gas. Filled or installed to increase the area.

  The composite heat exchanger 13 includes a heat exchanger 16 and water tanks such as a condensed water tank 14, a battery cooling water tank 30, and a pure water tank 31, and before the power generation operation of the fuel cell power generation system of the present invention. In addition, pure water from which impurities have been removed in advance and whose conductivity has been reduced is supplied to each water storage tank.

  That is, the condensed water tank 14 is supplied with the reformed gas condensed water 32 obtained by cooling the reformed gas before being introduced into the CO selective oxidizer, and the anode exhaust gas condensed water obtained by cooling the battery anode exhaust gas 7. 11, the reformer combustion exhaust gas condensed water obtained by cooling the combustion exhaust gas 15 obtained by burning the anode exhaust gas 7 from which the anode exhaust gas condensed water 11 has been removed, and the battery cathode exhaust gas 17 are cooled. The obtained cathode exhaust gas condensed water is stored.

  Here, the reformer combustion exhaust gas condensed water and the cathode exhaust gas condensed water are water that has been cooled and condensed by the heat exchanger 16, and travels through the partition plate 37 disposed under the heat exchanger 16 to pass through the condensed water tank 14. It is configured to flow into. The condensed water in the condensed water tank 14 is configured to be supplied to the water purification device 33 after the temperature is reduced by the heat exchanger 36 via the pump 35. As a heat source for the heat exchanger 36, exhaust heat recovery circulating water 10 exiting the heat exchanger 8, air before being introduced into the cathode 5b, or the like is used.

  Here, a reformed gas condensate 32 pipe is connected to the drain pipe 34 that discharges excess water from the condensate tank 14 to the outside of the fuel cell power generation system, and the condensate tank 14 is in operation during the power generation operation of the fuel cell power generation system. When the amount of water is excessive, the reformed gas condensate 32 is led out of the system, and when the water in the condensate tank 14 is insufficient, it is introduced into the condensate tank 14. .

  In the water purification device 33, the upstream side is filled with the cation exchange resin 23a and the downstream side is filled with the anion exchange resin 23b, and the condensed water in the condensed water tank 14 is supplied to the pump 35. After the cation and the anion are removed, the pure water tank 31 is supplied. The pure water stored in the pure water tank 31 is supplied to the fuel reforming system 2 as the reformed water 3 via the pump 25 and used as fuel reformed water.

  At this time, the flow rate of the water supplied from the condensed water tank 14 to the pure water tank 31 via the water purification device 33 is made larger than the flow rate of the reforming water 3, whereby the pure water tank 31 to the battery cooling water tank 30. Pure water overflows. The water in the battery cooling water tank 30 is circulated and introduced into the fuel cell main body 5 as the battery cooling water 18 by the battery cooling water pump 21 so that the fuel cell main body 5 is maintained at an optimum operating temperature.

  In the present embodiment, the battery cooling water 18 exiting the fuel cell body 5 is branched in two directions, and one line 18a (corresponding to the first branch line in the claims) is connected to the water purification device 33. The other line 18b (corresponding to the second branch line in the claims) is connected to the decarboxylation tower 19. A first shutoff valve 40 is installed in the line 18 a connected to the water purification device 33, and a second shutoff valve 39 is installed in the line 18 b connected to the decarbonation tower 19. A temperature detector 38 is installed on the upstream side of the water purification device 33.

  Then, after the fuel cell power generation system is activated, the second value until the detection value by the temperature detector 38 reaches a predetermined temperature set below the heat-resistant temperature of the ion exchange resin filled in the water purification device 33. The shutoff valve 39 is closed and the first shutoff valve 40 is opened. Thereby, after starting the fuel cell power generation system, the battery cooling water 18 exiting the fuel cell main body 5 is introduced into the water purification device 33 and purified, and then passes through the pure water tank 31 to the battery cooling water tank 30. The fuel cell main body 5 is further circulated and introduced by the battery cooling water pump 21.

  On the other hand, when the detected value by the temperature detector 38 becomes equal to or higher than a predetermined temperature set below the heat resistant temperature of the ion exchange resin filled in the water purification device 33, the first shutoff valve 40 is closed and the second shutoff valve 40 is closed. The shut-off valve 39 is configured to open. Thereby, the battery cooling water 18 exiting the fuel cell main body 5 is introduced into the decarbonation tower 19 together with the cathode exhaust gas 17, the carbon dioxide in the water is reduced, and the temperature is further reduced by the heat exchanger 22, and then the battery It is returned to the cooling water tank 30 and circulated and introduced into the fuel cell main body 5 by the battery cooling water pump 21.

  As described above, according to the present embodiment, it is possible to quickly and efficiently remove impurities generated during the stop of the fuel cell power generation system and accumulated in the battery cooling water 18 at the time of starting the system, and Since the amount of treated water during power generation operation is small, the water purification device 33 can be downsized. As a result, it is possible to provide a highly reliable fuel cell power generation system that can keep the conductivity of the battery cooling water 18 low over a long period of time.

(2) Second Embodiment Next, a second embodiment of the present invention will be described with reference to FIG. FIG. 2 shows a three-way valve 41 at a branch point between a line 18a connected to the water purification device 33 and a line 18b connected to the decarbonization tower 19 instead of the shutoff valves 39 and 40 used in the first embodiment. It is characterized by having installed. The operation of the fuel cell power generation system is the same as that in the first embodiment, and a description thereof will be omitted.

  That is, in this embodiment, after the fuel cell power generation system is activated, the detected value by the temperature detector 38 is set to a predetermined temperature set below the heat resistant temperature of the ion exchange resin filled in the water purification device 33. Until this time, the three-way valve 41 is configured to open to the water purification device 33 side. Thereby, after starting the fuel cell power generation system, the battery cooling water 18 exiting the fuel cell main body 5 is introduced into the water purification device 33 and purified, and then passes through the pure water tank 31 to the battery cooling water tank 30. The fuel cell main body 5 is further circulated and introduced by the battery cooling water pump 21.

  On the other hand, when the detected value by the temperature detector 38 becomes equal to or higher than a predetermined temperature set below the heat-resistant temperature of the ion exchange resin filled in the water purification device 33, the three-way valve 41 is opened to the decarboxylation tower 19 side. It is configured as follows. Thereby, the battery cooling water 18 exiting the fuel cell main body 5 is introduced into the decarbonation tower 19 together with the cathode exhaust gas 17, the carbon dioxide in the water is reduced, and the temperature is further reduced by the heat exchanger 22, and then the battery It is returned to the cooling water tank 30 and circulated and introduced into the fuel cell main body 5 by the battery cooling water pump 21.

  As described above, according to the present embodiment, as in the first embodiment, impurities generated while the fuel cell power generation system is stopped and accumulated in the battery cooling water 18 can be quickly and efficiently removed at the time of startup. Since the amount of treated water during the power generation operation is small, the water purification device 33 can be downsized. As a result, it is possible to provide a highly reliable fuel cell power generation system that can keep the conductivity of the battery cooling water 18 low over a long period of time.

(3) Third Embodiment Next, a third embodiment of the present invention will be described with reference to FIG. This embodiment is a modification of the first embodiment, wherein the composite heat exchanger 13 used in the first embodiment is divided into a heat exchanger 42 and a water tank 43, and the fuel cell main body 5 is ejected. The battery cooling water 18 is first cooled by the heat exchanger 22 and then introduced into the decarbonation tower 19 or the water purification device 33. The operation of the fuel cell power generation system is the same as that in the first embodiment, and a description thereof will be omitted.

  That is, in this embodiment, after the fuel cell power generation system is activated, the detected value by the temperature detector 38 is set to a predetermined temperature set below the heat resistant temperature of the ion exchange resin filled in the water purification device 33. Until this happens, the second shut-off valve 39 is closed and the first shut-off valve 40 is opened. Thereby, after starting the fuel cell power generation system, the battery cooling water 18 exiting the fuel cell main body 5 is first cooled by the heat exchanger 22 and then introduced into the water purification device 33 to be purified. It returns to the battery cooling water tank 30 through the tank 31, and is further circulated and introduced into the fuel cell main body 5 by the battery cooling water pump 21.

  On the other hand, when the detected value by the temperature detector 38 becomes equal to or higher than a predetermined temperature set below the heat resistant temperature of the ion exchange resin filled in the water purification device 33, the first shutoff valve 40 is closed and the second shutoff valve 40 is closed. The shut-off valve 39 is configured to open. Thereby, the battery cooling water 18 exiting the fuel cell main body 5 is first cooled by the heat exchanger 22 and then introduced into the decarbonation tower 19 together with the cathode exhaust gas 17, and after the carbon dioxide in the water is reduced, the battery It is returned to the cooling water tank 30 and circulated and introduced into the fuel cell main body 5 by the battery cooling water pump 21.

  Thus, according to this embodiment, the temperature of the battery cooling water 18 is lowered by installing the decarbonation tower 19 and the branch lines 18a and 18b to the water purification device 33 on the downstream side of the heat exchanger 22. After that, since the battery cooling water 18 can be sent to the water quality purification device 33 for a long time after activation, the initial water quality of the battery cooling water 18 can be further improved. . As a result, it is possible to provide a highly reliable fuel cell power generation system that can keep the conductivity of the battery cooling water 18 low over a long period of time.

(4) Other Embodiments In the above-described embodiment, when the detected value of the temperature detector 38 provided on the upstream side of the water purification device 33 reaches a predetermined temperature, the battery cooling water 18 at the time of starting the fuel cell power generation system. Is switched from the water purification device 33 and returned to the battery cooling water tank 30 through the decarbonation tower 19, but the inlet temperature of the water purification device 33 reaches a predetermined temperature from the start of the fuel cell power generation system. If the time until the time is already known, the battery cooling water 18 is introduced into the water purification device 33 from the start of the fuel cell power generation system until a predetermined time is reached. The temperature detector 38 can be omitted by the procedure of returning to the battery cooling water tank 30 through the decarbonation tower 19.

  In the above-described embodiment, the heat supply system using the exhaust heat recovery circulating water 10 introduced from the hot water storage tank 9 into the fuel cell package 1 is taken up. However, the supply form of heat to the use destination is the hot water storage tank. The medium flowing through the exhaust heat recovery circulation system is not limited to water.

  Further, when the battery cooling water exiting the fuel cell is passed through the line 18 a connected to the water purification device 33 to the water purification device 33, the water flow from the condensed water tank 14 to the water purification device 33 is performed. May be configured to be stopped. Thereby, the purification efficiency of the battery cooling water at the time of starting can be further improved.

The block diagram which shows 1st Embodiment of the fuel cell power generation system of this invention. The block diagram which shows 2nd Embodiment of the fuel cell power generation system of this invention. The block diagram which shows 3rd Embodiment of the fuel cell power generation system of this invention.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 ... Fuel cell package 2 ... Fuel reforming system 3 ... Reformed water 4 ... Reformed gas 5 ... Fuel cell main body 5a ... Anode 5b ... Cathode 6 ... Air blower 7 ... Anode exhaust gas 8 ... Heat exchanger 9 ... Hot water storage tank 10 ... exhaust heat recovery circulating water 11 ... anode exhaust gas condensate 12 ... reformer burner 13 ... composite heat exchanger 14 ... condensate water tank 15 ... combustion exhaust gas 16 ... heat exchanger 17 ... anode exhaust gas 18 ... battery cooling water 19 ... desorption Carbonic acid tower 21 ... Battery cooling water pump 22 ... Heat exchanger 23a ... Cation exchange resin 23b ... Anion exchange resin 25 ... Reformed water pump 30 ... Battery cooling water tank 31 ... Pure water tank 32 ... Reformed gas condensed water 33 ... water purification device 34 ... water distribution pipe 35 ... pump 36 ... heat exchanger 37 ... partition plate 38 ... temperature detector 39 ... second shut-off valve 40 ... first shut-off valve 41 ... three-way valve 42 ... heat Exchanger 43 ... water tank

Claims (7)

Using a hydrocarbon-based fuel as a raw fuel, a fuel reforming system that produces a hydrogen-rich gas by a steam reforming reaction, and a hydrogen-rich gas produced by the fuel reforming system as a fuel, and generating oxygen using air oxygen as an oxidant A fuel cell main body, a first water circulation system in which battery cooling water for maintaining the fuel cell at an operating temperature returns from the water tank to the water tank through the fuel cell, and a water purification device from the water tank. In a fuel cell power generation system comprising a second water circulation system passing back to the water tank,
The first water circulation system is composed of a first branch line connected to the water purification device and a second branch line returning to the water tank, and switching means for switching both branch lines is provided. ,
Until the predetermined time is reached after starting the fuel cell power generation system, the switching means is switched to the first branch line side, and the battery cooling water exiting the fuel cell is passed through the water purification device,
After the predetermined time has elapsed, the fuel cell power generation system is configured such that the switching means is switched to the second branch line side so that the cell cooling water exiting the fuel cell is returned to the water tank. Temperature detection means is provided upstream of the water purification device,
2. The fuel cell power generation system according to claim 1, wherein the predetermined time is a time from when the fuel cell power generation system is activated until a detection value of the temperature detection unit reaches a predetermined temperature.   The fuel cell power generation system according to claim 1 or 2, wherein the switching means is a shut-off valve installed in each of the first branch line and the second branch line.   3. The fuel cell power generation system according to claim 1, wherein the switching unit is a three-way valve installed at a branch point of the first branch line and the second branch line. 4.   The fuel cell power generation system according to any one of claims 1 to 4, wherein the second branch line is provided with a decarboxylation tower that reduces the concentration of carbon dioxide in water.   When battery cooling water that has exited the fuel cell is being passed through the first branch line to the water purification device, water flow to the water purification device through the second water circulation system is stopped. The fuel cell power generation system according to any one of claims 1 to 5, wherein the fuel cell power generation system is configured as described above. The water tank includes a condensed water tank for storing at least one condensed water from the condensed water from the fuel reforming system and the condensed water from the cathode exhaust; a cooling water tank for storing battery cooling water discharged from the fuel cell; It is composed of three tanks of pure water tanks for storing water passed from the condensed water tank to the water purification device,
Surplus water in the pure water tank is led to the battery cooling water tank, surplus water in the battery cooling water tank is led to the condensate water tank, and surplus water in the condensate water tank is discharged out of the fuel cell power generation system. The fuel cell power generation system according to any one of claims 1 to 6, wherein the fuel cell power generation system is configured as described above.