JP2010073550A - Fuel cell power generating device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a highly reliable fuel cell power generating device of which the cooling water system equipment or the like is surely and inexpensively prevented from being broken owing to freezing of water even in a low temperature environment. <P>SOLUTION: In the fuel cell power generating device, a reformer, a fuel cell body, and the cooling water system equipment are housed in a package 11, and a plurality of air intake ports 12a, 12b in order to introduce ventilation air into the package and an air exit port 14 equipped with a ventilation fan 13 to exhaust air in the package are installed in the package 11. At the intake port 12b having the smallest intake air flow passage up to the cooling water system equipment out of the air intake ports, an opening/closing means 30 is installed which is constituted so as to close the air intake port 12b when the external air temperature becomes equal to or lower than a predetermined threshold value. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to a fuel cell power generator configured by housing a reformer, a fuel cell main body, and a cooling water system device in the same package. More specifically, the present invention relates to water in a cooling water system device that is a concern during winter. The present invention relates to a fuel cell power generator that prevents freezing.

  The package type fuel cell power generation device is operated by installing main components such as a reformer, a fuel cell main body, and a cooling water system device in the same package and installed outdoors. Such a package type fuel cell power generator always provides a certain amount of ventilation in the package, regardless of whether it is in summer or winter, for the purpose of protecting the flammable gas from the fuel cell body. It has been broken. In addition, the outdoor temperature rises to close to 40 ° C. during the summer, but heat is released from equipment that is maintained at a high temperature during operation (hereinafter referred to as “high temperature equipment”), such as a reformer and a fuel cell main body. Sometimes, when the cooling water system equipment or the electrical system is overheated, the life of the water treatment resin, etc. may be significantly impaired, or the electrical system may be thermally damaged. In order not to overheat the components, measures are taken such as flowing a large amount of ventilation, or ventilating high-temperature equipment and cooling water system equipment by separate routes.

  By the way, since the reformer and the fuel cell main body are maintained at a high temperature during operation of the fuel cell power generator, the cooling water flowing through these devices is frozen even if the outside air temperature is below freezing point. There is little possibility to do. On the other hand, since the cooling water system equipment hardly generates heat, in an environment where the outside air temperature can be below freezing point, in order to prevent the water in the cooling water system equipment from freezing, a pipe heat insulation heater, a steam trace, a space heater, etc. It has been conventionally performed to heat the cooling water system equipment by arranging the heat generator in the package.

  FIG. 9 is a cross-sectional view showing a basic configuration of this type of conventional fuel cell power generator. In this figure, 1 is a package, 2a and 2b are intake ports arranged in the package 1, 3 is a ventilation fan incorporated in the package 1, and 4 is an exhaust section. The air inlet 2 a is provided in the lower part of the side wall of the package close to the high temperature device 6, and the air inlet 2 b is provided in the lower part of the side wall of the package close to the cooling water system device 7. Reference numeral 5 denotes a heat generator for heating the inside of the package 1, and reference numeral 8 denotes a control device for controlling the ventilation fan 3 and the heat generator 5. In the fuel cell power generation device of this configuration, during power generation in which water is likely to freeze (mainly in winter), the drive amount of the ventilation fan 3 and the heat generation amount of the heat generator 5 are controlled by the control device 8, thereby The inside of 1 is heated to prevent the cooling water system equipment 7 from freezing.

Further, the fuel cell power generator disclosed in Patent Document 1 below measures the outside air temperature with a temperature sensor, and when the measured temperature falls below a predetermined threshold, the hot water heated by the heater is passed through the cooling water system equipment. To prevent freezing. In addition, the fuel cell power generator disclosed in Patent Document 2 below keeps the cooling water system equipment at a predetermined temperature or higher by flowing hot water stored in a hot water storage tank through a freezing prevention pipe inside the package. Is going to prevent. Further, the fuel cell power generator disclosed in Patent Literature 3 is designed to prevent freezing by minimizing the influence of outside air by closing the exhaust port and reversing the ventilation fan when the operation is stopped.
Japanese Patent Application Laid-Open No. 11-214025 Japanese Patent Laid-Open No. 2003-282105 JP 2006-140050 A

  In a package type fuel cell power generator installed and used outdoors, various measures are taken so that the cooling water system equipment does not freeze during a power generation operation in winter.

  However, in the example shown in FIG. 9, for example, the portion heated by the ventilation air is limited to a specific direction in which the ventilation air flows, so that it is not always sufficient as a freeze prevention measure for various cooling water system devices dispersed in the package. There was a difficulty that it was not. Further, since the heat generator 5 is necessary, the power of the auxiliary machine is increased because the heat generator 5 is turned on and off during the power generation of the fuel cell power generation apparatus, and the power generation efficiency is lowered.

  In addition, the methods disclosed in Patent Document 1 and Patent Document 2 require additional equipment such as a hot water reservoir, so that not only the cost of the apparatus increases but also the entire apparatus tends to be enlarged.

  Further, in the method disclosed in Patent Document 3, since introduction of outside air is restricted, there is anxiety in terms of explosion prevention, and there is a problem that it is difficult to apply during operation of the fuel cell power generator.

  Accordingly, an object of the present invention is to provide a highly reliable fuel cell power generation device that is reliably and inexpensively prevented from being damaged by freezing of water in a cooling water system device or the like even in a low temperature environment.

In order to achieve the above object, a fuel cell power generator according to the present invention generates power by a reaction between a reformer that steam reforms hydrocarbons to produce a hydrogen-containing gas, and the hydrogen-containing gas and oxidant gas. A fuel cell main body and a cooling water system device that cools the fuel cell main body are housed in a package. The package includes a plurality of air inlets for introducing air for ventilation into the package, In the fuel cell power generator provided with an exhaust port provided with a ventilation fan for exhausting air,
Among the intake ports, an opening / closing means is provided at the intake port having the shortest intake flow path to the cooling water system equipment,
The opening / closing means is configured to close the intake port when the outside air temperature falls below a preset threshold value.

  According to the fuel cell power generation device of the present invention, when the outside air temperature falls below a preset threshold value, the intake port with the shortest intake flow path to the cooling water system device is closed, so that the cooling water system device is cooled by the intake air. Hateful. Further, since the reformer and the fuel cell main body are maintained at a high temperature during operation, the cooling water system equipment is heated by the air heated by the heat radiation from these devices. For this reason, even when the temperature is low, an abnormal temperature drop of the cooling water system device can be prevented and freezing of the cooling water can be prevented, so that power can be stably generated over a long period of time.

  The fuel cell power generator of the present invention is preferably configured such that a baffle plate is disposed in front of the ventilation fan, and air enters through a gap between the baffle plate and the inner wall of the package. According to this aspect, when the outside air temperature becomes equal to or lower than a preset threshold value, the air that has been preheated by the reformer or the fuel cell main body is easily introduced into the region where the cooling water system equipment is disposed. The cooling water system equipment is heated by the air, and the abnormal temperature drop of the cooling water system equipment can be more effectively prevented.

  The opening / closing means of the fuel cell power generator of the present invention is configured by attaching an opening / closing member to a hinge made of a member selected from a bimetal, a shape memory alloy, and a laminate of a shape memory alloy and a leaf spring. It is preferable. According to this aspect, since the shape of the hinge changes according to the temperature, the opening / closing means can be automatically operated in accordance with the temperature change of the outside air without using electrical or mechanical means, and the operating cost can be reduced. .

  The opening / closing means of the fuel cell power generator of the present invention is preferably configured to open and close the opening / closing member by thermal expansion of gas or liquid. In particular, it is preferable that a gas or liquid is enclosed in a Bourdon tube or a bellows, and the opening / closing member is opened and closed by thermal expansion of the enclosed gas or liquid. According to this aspect, since the Bourdon tube and the bellows are deformed according to the pressure, the opening / closing means can be automatically operated in accordance with the temperature change of the outside air without using an electrical or mechanical means, and the operation cost is reduced. it can.

  In the fuel cell power generator of the present invention, it is preferable that a heat collecting paint is applied to the surface of the opening / closing member. During the closing operation, the opening / closing member is heated by the heat collection by sunlight, so that the water in the cooling water system equipment can be effectively prevented from freezing even when the temperature in the vicinity of the cooling water system equipment rises and the outside air temperature decreases. .

  The open / close member of the fuel cell power generation device of the present invention has an uneven surface, and a heat collecting paint is applied to the upper surface during the closing operation, and a reflective paint is applied to at least some other surfaces. Preferably it is. Since the heat collecting paint is applied to the upper surface during the closing operation, the open / close member is heated by the heat collected by sunlight, the temperature in the vicinity of the cooling water system rises, and even if the outside air temperature falls, the cooling water system It is possible to effectively prevent water in the device from freezing. In addition, since the reflective coating is applied to the other surfaces, it is possible to suppress the temperature inside the package from rising during steady operation, and to suppress thermal damage to the components of the fuel cell power generator.

  According to the fuel cell power generator of the present invention, it is possible to prevent an abnormal temperature drop of the cooling water system equipment and to prevent the cooling water from freezing.

  1 and 2 show an embodiment of a schematic configuration diagram of a fuel cell power generator according to the present invention. FIG. 1 is a configuration diagram during steady operation of the device, and FIG. 2 illustrates a low temperature operation of the device. FIG. The fuel cell power generation device 10 is configured such that an intake port 12b provided in the vicinity of the cooling water system device 17 opens and closes according to the outside air temperature with respect to the conventional fuel cell power generation device shown in FIG. It is mainly different in point. Hereinafter, it demonstrates still in detail using drawing.

  In the fuel cell power generation apparatus 10, a high temperature device 16 and a cooling water system device 17 are accommodated in a package 11.

  Although not particularly illustrated, the high-temperature device 16 is mainly composed of a reformer that steam-reforms hydrocarbons to generate a hydrogen-containing gas, and a fuel cell main body that generates power by reaction with the hydrogen-containing gas and the oxidant gas. It is configured.

  Although not specifically shown, the cooling water system device 17 recovers and stores water from gas discharged from the reformer and the fuel cell main body, and decarboxylates and dewaters the water in the recovered water storage tank. Mainly composed of a water treatment device that performs ion treatment, impurity removal, etc., a treated water storage tank that stores the treated water and uses it as cooling water for the fuel cell body, and piping that connects them Has been. The water in the treated water storage tank can also be used for humidification of reformed water used for the reforming reaction in the reformer and hydrogen-containing gas and oxidant gas supplied to the fuel cell power generator. it can.

  An exhaust port 14 is provided on the upper wall of the package 11, and a ventilation fan 13 that exhausts air in the package 11 is disposed in front of the exhaust port 14. The driving amount of the ventilation fan 13 is controlled by the control device 18. Further, a baffle plate 19 is disposed in front of the ventilation fan 13 so that air enters through a gap S between the baffle plate 19 and the inner wall of the package.

  In the lower portion of the side wall of the package 11, intake ports 12 a and 12 b for introducing ventilation air into the package are provided.

  The air inlet 12 a is provided in the lower part of the side wall of the package adjacent to the high temperature device 16. In this embodiment, there is one intake port 12a, but a plurality of intake ports 12a may be provided.

  The air inlet 12b is provided in the lower part of the side wall of the package close to the cooling water system device 17, and the air inlet 12b is provided with an opening / closing device 30 including an opening / closing member 32. In this embodiment, there is one intake port 12b, but a plurality of intake ports 12b may be provided.

  In the present invention, the opening / closing device 30 only needs to be configured so as to be able to open and close the intake port 12b according to the outside air temperature, and opens and closes the intake port 12b by opening and closing the opening and closing member by electric power. And the one that automatically opens and closes the inlet 12b without using electrical power to open and close the air inlet 12b. In particular, the latter is automatically operated without using the electrical power. The opening / closing means that is operated by the method can be preferably employed because it can reduce the operating cost and is economically superior.

  As an open / close device using electric power, for example, a temperature sensor is provided outside the package, and when the detection value by the temperature sensor falls below a preset threshold value, the open / close member is closed and the intake port 12b is closed. What was comprised so that it might be mentioned.

  In addition, as an opening / closing device that does not use electric power, for example, an opening / closing member is attached to a hinge made of a member selected from a bimetal, a shape memory alloy, and a laminate of a shape memory alloy and a leaf spring. What is described is a preferred example. This will be described with reference to FIGS. In the opening / closing device 30 ′, an opening / closing member 32 is attached to the end of the opening of the wall surface of the package 11 via a hinge 31. Moreover, a rain return 33 for preventing rain from blowing is fixed to the opening / closing member 32 in the vicinity of the hinge 31. For example, when the hinge 31 is formed of bimetal, a U-shape is formed when the temperature exceeds a predetermined temperature (for example, 5 ° C.) (see FIG. 3), and the curve extends when the temperature is lower than the predetermined temperature (for example, 5 ° C. or less). By designing so as to make such a deformation (see FIG. 4), the shape of the hinge 31 can change the opening / closing operation of the intake port 12b without using power. Further, when the hinge 31 is formed of a laminated body of a shape memory alloy and a leaf spring, the open state is maintained by the restoring force of the shape memory alloy when a predetermined temperature is exceeded, and the closing operation is performed by the spring force below the predetermined temperature. By designing, the inlet 12b can be opened and closed without using power. Further, when, for example, a bi-directional shape memory alloy is used as the shape memory alloy, the same effect can be obtained with the shape memory alloy alone.

  Moreover, as another aspect, the opening / closing apparatus shown to FIG.5, 6 is mentioned as an example. In the opening / closing device 30 '', an opening / closing member 32 is disposed at the upper end portion of the opening of the wall surface of the package 11 via a hinge 31a, and a gas having a high thermal expansion coefficient such as air or nitrogen is formed below the opening, A lifting device 35 provided with a Bourdon tube or bellows, in which a liquid having a high thermal expansion coefficient such as alcohol or mercury is enclosed, is disposed. The opening / closing member 32 and the lifting device 35 are connected via a crank 36. In this opening / closing device 30 '', when the outside air temperature is high, the gas or liquid enclosed in the Bourdon tube and the bellows expands and the pressure rises, so the lifting device 35 is raised and the opening / closing member 32 is pushed up, The intake port 12b opens. On the other hand, when the outside air temperature is low, the pressure in the Bourdon tube or the bellows becomes low, so that the elevating device 35 is lowered, the opening / closing member 32 is closed, and the air inlet 12b is sealed.

  In the fuel cell power generator of the present invention, the open / close member 32 is preferably coated on the surface with a heat collecting paint such as a black non-reflective paint. If the heat collecting paint is applied to the surface of the opening / closing member 32, the surface of the opening / closing member 32 is heated by the heat collection by sunlight during the closing operation, so that the temperature of the region where the cooling water system device 17 is installed rises. And can be heated.

  In the fuel cell power generation device having the above configuration, during steady operation, the ventilation air discharged by the ventilation fan 14 is separately introduced from the intake ports 12a and 12b by negative pressure as shown in FIG. The air introduced into the package 11 from the air inlet 12a ventilates the air in the region where the high temperature equipment 16 is installed, and is exhausted to the outside through the air outlet 14 and introduced into the package 11 from the air inlet 12b. The air ventilates the air in the area where the cooling water system device 17 is installed and exhausts the air from the exhaust port 14, ventilates the high temperature device 16 and the cooling water system device 17 through different paths, and cools the cooling water system device 17. Is operated so as not to be overheated by heat radiation from the high temperature equipment 16.

  On the other hand, when the outside air temperature becomes equal to or lower than a preset threshold value (for example, 5 ° C. or less), the opening / closing member 32 is closed and the intake port 12b is closed, so that the introduction of outside air from the intake port 12b is suppressed. Outside air is introduced only from 12a. The air introduced from the air inlet 12a is heated by heat radiation from the high temperature equipment 16, and the flow of the ventilation air to the ventilation fan 13 is divided by the baffle plate 19, so that the cooling water system equipment 17 is installed. Part of the ventilation air heated by the heat radiation from the high temperature device 6 flows in the region and is heated. As a result, the abnormal temperature drop of the cooling water system device 17 can be prevented even at a low temperature, the water inside the cooling water system device 17 can be prevented from freezing, and the operation can be stably performed for a long time.

  A second embodiment of the fuel cell power generator of the present invention will be described with reference to FIGS. FIG. 7 is a schematic view of the fuel cell power generation apparatus during steady operation of the intake port 12b, and FIG. 8 is a schematic view at low temperatures. The same portions as those of the first embodiment are denoted by the same reference numerals and the description thereof is omitted.

  In this embodiment, the opening / closing device 30 ″ ′ has the surface of the opening / closing member 32a formed in a concavo-convex shape, and the heat collecting paint is applied to the surface (surface A in the drawing) which becomes the upper surface when in the closed state, It differs from the above embodiment in that a reflective paint such as silver or white is coated on at least one of the other surfaces (surface B in the figure).

  In this embodiment, the unevenness is formed on the surface of the opening / closing member 32a by corrugation, but the unevenness may be formed by welding a plate to the surface of the flat plate, or the unevenness may be formed by mold molding. .

  According to this embodiment, since the opening / closing member 32a is exposed to sunlight on the reflective coating surface during steady operation, the opening / closing member 32a is not easily overheated by sunlight, and the temperature rise in the package can be suppressed. On the other hand, at the time of the closing operation, the opening / closing member is heated by the heat collection by sunlight, and the temperature in the vicinity of the cooling water system device 17 rises, so that the water in the cooling water system device 17 is effectively frozen even when the outside air temperature decreases. Can be prevented.

It is the schematic at the time of steady operation of the fuel cell power generator of the present invention. It is the schematic at the time of low temperature operation of the fuel cell power generator of the present invention. It is the schematic at the time of the steady operation of the inlet port of the fuel cell power generator. It is the schematic at the time of the low temperature driving | operation of the inlet port of the fuel cell power generator. It is the schematic at the time of the steady operation of the inlet port of the other example of the fuel cell power generator. It is the schematic at the time of the low temperature driving | operation of the inlet port of the other example of the fuel cell power generator. It is the schematic at the time of the steady operation of the inlet of the fuel cell power generator of 2nd embodiment of this invention. It is the schematic at the time of the low temperature driving | operation of the inlet port of the fuel cell power generator. It is the schematic of the conventional fuel cell power generator.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1,11: Package 2a, 2b, 12a, 12b: Intake port 3, 13: Ventilation fan 4, 14: Exhaust port 5: Heat generator 6, 16: High temperature apparatus 7, 17: Cooling water system apparatus 8, 18: Control apparatus 10: Fuel cell power generator 19: Baffle plate 30: Opening / closing device 31: Hinge 32, 32a: Opening / closing member 35: Lifting device 36: Crank

Claims (6)

A reformer that steam-reforms hydrocarbons to produce a hydrogen-containing gas, a fuel cell body that generates power by reaction with the hydrogen-containing gas and an oxidant gas, and a cooling water system device that cools the fuel cell body Is stored in a package, and the package is provided with a plurality of air intakes for introducing air for ventilation into the package, and an exhaust provided with a ventilation fan for exhausting the air in the package In battery power generators,
Among the intake ports, an opening / closing means is provided at the intake port having the shortest intake flow path to the cooling water system equipment,
The fuel cell power generator according to claim 1, wherein the opening / closing means is configured to close the intake port when the outside air temperature becomes a preset threshold value or less.   2. The fuel cell power generator according to claim 1, wherein a baffle plate is disposed in front of the ventilation fan so that air enters through a gap between the baffle plate and the inner wall of the package.   The opening / closing means is configured by attaching an opening / closing member to a hinge made of a member selected from a bimetal, a shape memory alloy, and a laminate of a shape memory alloy and a leaf spring. Fuel cell power generator.   The said opening / closing means is configured so that a gas or liquid is enclosed in a Bourdon tube or a bellows, and the opening / closing member is opened and closed by thermal expansion of the enclosed gas or liquid. Fuel cell power generator.   The fuel cell power generator according to claim 3 or 4, wherein a heat collecting paint is applied to a surface of the opening / closing member.   6. The open / close member according to claim 5, wherein the opening / closing member has irregularities on a surface thereof, a heat collecting paint is applied to a surface which becomes an upper surface during a closing operation, and a reflective paint is applied to at least a part of the other surfaces. Fuel cell power generator.