JP2001273916A - Fuel cell cogeneration system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a fuel cell cogeneration system that can be installed in a house of an urban area without a margin site. SOLUTION: A raw material fuel tank 2 is used as a heat storage tank to store the waste heat of a reformer 3 and a fuel cell 4, and the waste heat stored in the heat storage tank is utilized. Because the raw material fuel tank 2 is used as the heat storage tank, a conventional heat storage tank becomes unnecessary, and a more miniaturization of the fuel cell cogeneration system 1 can be aimed at. By realizing the miniaturization, the fuel cell cogeneration system 1 is made possible to be installed in a house of an urban area without a margin area. In addition, the heat efficiency of the whole fuel cell cogeneration system 1 can be improved, since the kerosene 21 in the raw material fuel tank is heated with the waste heat.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a raw fuel tank for storing raw fuel, a reformer for generating a hydrogen-rich reformed gas from the raw fuel, and power generation using hydrogen of the reformed gas as fuel. The present invention relates to a fuel cell cogeneration system provided with a fuel cell to perform.

[0002]

2. Description of the Related Art Conventionally, a fuel cell power generation system in which a reformer generates a hydrogen-rich reformed gas from a raw fuel and uses the reformed gas as a fuel to generate power in a fuel cell has been known. High temperature waste heat is generated from the battery. Therefore, a cogeneration system for supplying hot water and heating using the waste heat generated from the reformer and the fuel cell is being studied.

In this cogeneration system, a heat exchange device is provided between the reformer and the fuel cell, low-temperature water such as tap water flows through the heat exchange device, and the water is used as waste heat of the reformer and the fuel cell. By heating, hot water can be supplied as hot water. Here, when hot water is supplied, since it is necessary to instantaneously heat with a large amount of heat, for example, in a general household, a high temperature is set such that hot water can be used simultaneously in a plurality of places such as a shower and a washing surface. A hot water heater is used. However, if the water flowing to the heat exchanger is heated by the waste heat of the reformer and the fuel cell and is used immediately as hot water, high-output waste heat must be generated from the reformer and the fuel cell. There is a problem that the cogeneration system needs to be upsized and waste heat recovery is inefficient.

[0004] Therefore, the heat exchange device is connected to a heat storage tank such as a hot water storage tank, and the waste heat of the reformer or the fuel cell recovered by the heat exchange device is stored in the heat storage tank. A cogeneration system that supplies hot water has been proposed (see Japanese Patent Application Laid-Open No. 11-97044).

[0005]

However, the size of the heat storage tank that constitutes such a cogeneration system requires a capacity of at least about 100 liters even for a general home, so that it is required to be installed in an urban house. As described above, when there is no room on the site, the heat storage tank cannot be arranged, which causes a problem that it is difficult to install the cogeneration system.

[0006] It is an object of the present invention to provide a fuel cell cogeneration system that can be installed in an urban house where there is no room on the site.

[0007]

According to the present invention, a reformer is used to generate a hydrogen-rich reformed gas from raw fuel supplied from a raw fuel tank, and the hydrogen of the generated reformed gas is used as fuel. A fuel cell cogeneration system that generates electricity with a battery, collects waste heat from the reformer and the fuel cell, and uses it as heat energy, and at least a part of the raw fuel tank includes the reformer and the fuel cell. The heat storage tank is configured to store at least one waste heat, and the fuel cell cogeneration system uses the waste heat stored in the heat storage tank. Here, as the raw fuel, a hydrocarbon-based liquid or solid, a methanol-based alcohol fuel, or the like can be used. Specifically, hydrocarbon liquids such as naphtha, gasoline, kerosene, light oil, heavy oil,
Alcohols such as methanol and ethanol can be exemplified. For home use, liquid hydrocarbons such as naphtha and kerosene, and alcohols such as methanol are preferred from the viewpoint of availability and handling. Further, as the fuel cell, a phosphoric acid fuel cell, a molten carbonate fuel cell, a solid electrolyte fuel cell, an alkaline fuel cell, a polymer electrolyte fuel cell, or the like can be employed. According to the present invention, since at least a part of the raw fuel tank is a heat storage tank, the conventional heat storage tank is reduced in size or becomes unnecessary.
The fuel cell cogeneration system can be reduced in size accordingly, so that it can be installed in urban residences where there is not enough room. Further, if the raw fuel tank is a heat storage tank, the raw fuel in the raw fuel tank is preheated, so that the thermal efficiency of the entire fuel cell cogeneration system can be improved.

In the above, it is preferable that a desulfurizing agent capable of removing sulfur compounds contained in the raw fuel is provided in the raw fuel tank. Here, as the desulfurizing agent, adsorbents such as activated carbon, porous silica, and zeolite;
transition metal compounds such as n, Cu, Fe, Co, Ni, P
Noble metal compounds such as t and Pd and those in which these are supported on a carrier such as silica, alumina, zeolite, diatomaceous earth, and clay compounds can be used. This makes it possible to easily remove the sulfur compounds contained in the raw fuel, thereby easily preventing the raw fuel tank from being corroded by the sulfur compounds, and also being used for the fuel cell. Sulfur poisoning of the reforming catalyst or the like can be prevented. In addition, in the raw fuel tank, a sufficient residence time of the raw fuel can be taken, so that the desulfurization reaction can sufficiently proceed, thereby obtaining almost pure raw fuel in the raw fuel tank. It becomes possible.

[0009] Further, around the above-mentioned raw fuel tank and / or
Alternatively, it is desirable that a heat storage material for storing waste heat stored in the raw fuel is provided inside. Here, as the heat storage material, use is made of melting and coagulation of brick, concrete, water or water in which metal salts and organic substances are dissolved, paraffin and higher alcohols, organic acids, esters, oils and fats, organic and inorganic salts, and the like. A latent heat storage material that performs heat storage using a heat storage material, and a material in which these latent heat storage materials are encapsulated in a capsule can be used. Thus, for example, if a heat exchanger is provided in the raw fuel tank and an inorganic salt or the like as a heat storage material is provided around the raw fuel tank, the heat exchanger and the raw fuel The waste heat from the reformer and the fuel cell, which is stored in the raw fuel after heat exchange, can be used for applications such as hot water supply, and can be stored in inorganic salts or the like. Thereby, heat storage efficiency can be improved.

Further, it is preferable that irregularities are formed on the inner wall surface of the raw fuel tank. This makes it possible to promote heat exchange between the raw fuel in the raw fuel tank and the heat storage material, thereby further improving the heat storage efficiency.

[0011]

Embodiments of the present invention will be described below with reference to the drawings. FIG. 1 shows a fuel cell cogeneration system 1 according to a first embodiment of the present invention. The fuel cell cogeneration system 1
Raw fuel tank 2 in which kerosene 21 as raw fuel is stored
, A reformer 3 and a fuel cell 4.

The reformer 3 is formed so as to generate a hydrogen-rich reformed gas by a steam reforming reaction from kerosene 21 and steam supplied from the raw fuel tank 2 via the raw fuel supply path 11. . In this steam reforming reaction,
Since a catalytic reaction at a high temperature is required, the kerosene 21 is burned to bring the reformer 3 to a predetermined temperature (for example, 600 to 700).
(° C). The exhaust gas generated by this combustion is discharged from an exhaust path (not shown). Further, the hydrogen-rich reformed gas generated by the reformer 3 is sent to a reformed gas supply path and supplied to the fuel cell 4. The fuel cell 4 is a polymer electrolyte fuel cell, and generates power using the reformed gas supplied from the reformer 3 as fuel.

As shown in FIG. 2, the raw fuel tank 2 is formed in a cylindrical shape with stainless steel, and has a heat storage section 12 made of an inorganic salt, which is a heat storage material for storing waste heat stored in kerosene, around the column. Is provided. Also, kerosene 2 which is a raw fuel and has a heat storage effect
1 is stored and two heat exchangers 22, 2
3 are provided. The two heat exchangers are a first heat exchanger 22 and a second heat exchanger 23. The first heat exchanger 22 is a pipe formed in a spiral shape, and
It is provided with a heating medium outlet 22A and a heating medium inlet 22B exposed on the surface. The second heat exchanger 23 is a pipe formed in a spiral shape and has a water supply port 23 </ b> A and a water supply port 23 </ b> B exposed on the surface of the heat storage unit 12. A water supply pipe such as a water pipe (not shown) is connected to the water supply port 23A, and a water supply pipe constituting a water supply path to the hot water supply system 13 is connected to the water supply port 23B.

A reformer 3 is connected to a lower portion of the raw fuel tank 2, and a raw fuel supply pipe 24 that forms the raw fuel supply path 11 is provided. Also, the raw fuel tank 2
A fuel supply port 25 for supplying kerosene 21 into the raw fuel tank 2 is formed in an upper part of the fuel tank 2. Further, a temperature sensor 26 is provided in the raw fuel tank 2. The temperature sensor 26 controls a circulation amount of water flowing through a heat medium circulation path 51 described later, and sets the temperature of the kerosene 21 to a desired temperature. In the raw fuel tank 2, a desulfurizing agent unit 27 filled with activated carbon, which is a desulfurizing agent capable of removing sulfur compounds contained in kerosene 21, is provided.
Is provided.

On the other hand, when the reformer 3 performs heating or the fuel cell 4 generates electric power, the reformer 3 and the fuel cell 4 generate high-temperature waste heat. This waste heat is
The heat is recovered by the heat exchange device 5. here,
As the heat exchange device 5, the heat of the reformer 3 and the fuel cell 4 is conveyed by blowing air, and water as a heat medium is circulated around the air flow path. There are a system in which water as a heat medium is circulated around the fuel cell 4 and waste heat is recovered in the water, and a system in which these two systems are combined. In order to efficiently recover waste heat, it is preferable to use a heat exchange device that circulates water around the reformer 3 and the fuel cell 4 and recovers waste heat into the water.

The heat exchanger 5 of this embodiment is of a type in which water is circulated around the reformer 3 and the fuel cell 4 and waste heat is recovered by the water. A first heat exchanger 22 provided in the first heat exchanger 22,
It is formed to include a reformer 3 and a heat medium circulation path 51 that circulates through the fuel cell 4. The heat medium circulation path 51 includes a first heat medium path 52 that interconnects the first heat exchanger 22 and the fuel cell 4 and a second heat medium path that interconnects the fuel cell 4 and the reformer 3. 53, and a third heat medium path 54 for interconnecting the reformer 3 and the first heat exchanger 22 with each other. Each path is formed by a pipe (not shown), and the water circulates through the pipe.

That is, the first heat medium path 52 described above is
The third heat medium path 54 is connected to the heat medium outlet 22 </ b> A of the first heat exchanger 22. In this way, by connecting the first heat exchanger 22 and the heat medium circulation path 51, water as a heat medium is transferred to the first heat exchanger 22 and the heat medium circulation path, as indicated by arrows in FIG. 5
1 and the waste water of the reformer 3 and the fuel cell 4 is recovered by the water, and heat is exchanged between water and kerosene 21 by the first heat exchanger 22 in the raw fuel tank 2. The recovered waste heat can be stored in the raw fuel tank 2. In addition, by connecting the second heat exchanger 23 with the water supply pipe and the water supply pipe, the tap water is supplied to the water supply port 23.
A to the second heat exchanger 23 and is heated by the heat stored in the raw fuel tank 2 to become hot water, and the water supply port 23B
And is supplied to the hot water supply system 13 through a water supply path.

Here, water is passed through the heat medium circulation path 51,
In recovering the waste heat of the reformer 3 and the fuel cell 4, it is preferable to form a circulation path so that water recovers the waste heat of the reformer 3 after recovering the waste heat of the fuel cell 4. In this way, the temperature of the waste heat is higher than that of the fuel cell 4 in the reformer 3.
Is higher, the heat is first exchanged with the fuel cell 4 having a lower temperature, the waste heat of the fuel cell 4 is recovered in water, and then the heat is exchanged with the reformer 3 having a higher temperature. By allowing the water to recover the waste heat of the reformer 3, the waste heat can be efficiently recovered.

Therefore, the waste heat recovered from the reformer 3 and the fuel cell 4 is supplied to the raw fuel tank 2 via the first heat exchanger 22.
The kerosene 21 inside is heated and stored, and tap water passed through the second heat exchanger 23 is heated by the kerosene 21 in the raw fuel tank 2. Thereby, hot water can be obtained in the hot water supply system 13. For these reasons, the raw fuel tank 2 itself is a heat storage tank. At this time, since the heat stored in the kerosene 21 is also stored in the heat storage unit 12, for example, even if the remaining amount of the kerosene 21 decreases, the temperature of the raw fuel tank 2 does not decrease.
Hot water of a desired temperature can be supplied by the heat stored in the heat storage unit 12, and the temperature of the supplied hot water can be kept constant. In addition, each heat exchanger 22,
23 is not limited to being provided in the raw fuel tank 2, for example,
It may be provided so as to be wound around the outer periphery of the raw fuel tank 2.

Next, the operation of the fuel cell cogeneration system 1 will be described below. First, when the reformer 3 generates a hydrogen-rich reformed gas from the kerosene 21 and steam by a steam reforming reaction, the reformed gas is supplied to the fuel cell 4 through a reformed gas supply path. You. The fuel cell 4 generates power using hydrogen in the reformed gas and oxygen in the atmosphere as fuel sources. On the other hand, water as a heat medium is circulating between the first heat exchanger 22 and the heat medium circulation path 51, and the water sent from the heat medium outlet 22 </ b> A of the first heat exchanger 22 is And the waste heat of the reformer 3 is recovered and returned to the first heat exchanger 22.
Then, heat exchange is performed between the water from which the waste heat has been recovered and the kerosene 21, and the kerosene 21 is heated. Also, the second heat exchanger 2
The tap water supplied to 3 is heated by the heat of the kerosene 21, turned into warm water, and sent out to the hot water supply system 13. Thereby, hot water can be used.

According to this embodiment, the following effects can be obtained. That is, since the raw fuel tank 2 is a heat storage tank, the conventional heat storage tank is not required, and the fuel cell cogeneration system 1 can be downsized accordingly. The fuel cell cogeneration system 1 can also be installed. In addition, since the kerosene 21 in the raw fuel tank 2 is preheated, the thermal efficiency of the entire fuel cell cogeneration system 1 can be improved.

Further, since the raw fuel tank 2 is provided with the desulfurizing agent unit 27 filled with activated carbon, the sulfur compound contained in the kerosene 21 can be easily removed. 2 can be easily prevented, and the reformer 3 can be prevented from poisoning the catalyst. Furthermore, in the raw fuel tank 2,
Since the residence time of the kerosene 21 can be sufficiently long, the desulfurization reaction can sufficiently proceed, and thus, almost pure kerosene 21 can be obtained in the raw fuel tank 2.

Further, since the first and second heat exchangers 22 and 23 are provided in the raw fuel tank 2 and the heat storage section 12 is provided around the raw fuel tank 2, the first heat exchanger 22 is provided.
The waste heat from the reformer 3 and the fuel cell 4 that is exchanged between the fuel and the kerosene 21 and stored in the kerosene 21 is used for applications such as hot water supply through the second heat exchanger 23, The heat can be stored in the heat storage unit 12. Thereby, heat storage efficiency can be improved.

FIG. 3 shows a fuel cell cogeneration system 1A according to a second embodiment of the present invention. Note that the same or equivalent components as those in the first embodiment are denoted by the same reference numerals, and description thereof will be omitted or simplified. In the present embodiment, the raw fuel tank 2 having a flat inner wall surface in the first embodiment is replaced with a raw fuel tank 2A having an uneven inner wall surface. Specifically, the raw fuel tank 2A
Is covered with a heat storage layer filled with a heat storage material, and irregularities are formed on an inner wall surface of the raw fuel tank 2A, and irregularities are formed at a boundary portion between the heat storage layer and the raw fuel tank 2A. ing. According to this embodiment, the same effects as those of the above embodiment can be obtained, and the raw fuel tank 2
The heat exchange between the kerosene 21 in A and the heat storage unit 12 can be promoted, whereby the heat storage efficiency can be further improved.

It should be noted that the present invention is not limited to the above-described embodiment, but includes other configurations that can achieve the object of the present invention, and also includes the following modifications.
For example, the heat storage material is not limited to being provided around the raw fuel tank 2, but may be provided inside the raw fuel tank 2 as shown in FIG. 4, for example. At this time, it is preferable to provide a heat insulating material 14 such as glass wool around the raw fuel tank 2. The thickness of the heat insulating material is about 10 mm
100 mm is preferred. Further, the heat storage material may be provided both around and inside the raw fuel tank 2, and the position thereof may be determined as appropriate upon implementation.

Further, in the first embodiment, the desulfurizing agent unit 27 is provided in the raw fuel tank 2; however, the present invention is not limited to this, and it may be provided separately in the fuel cell cogeneration system 1. May be determined appropriately.

[0027] The desulfurizing agent is not limited to activated carbon.
For example, porous silica, an adsorbent such as zeolite, Mn,
Transition metal compounds such as Cu, Fe, Co, Ni, Pt, P
noble metal compounds such as d and silica, alumina,
Those supported on carriers such as zeolite, diatomaceous earth, and clay compounds can be employed.

Further, the raw fuel is not limited to kerosene 21, but naphtha, gasoline, light oil, heavy oil, methanol, ethanol and the like can be used.

The fuel cell is not limited to a polymer electrolyte fuel cell, but may be, for example, a phosphoric acid fuel cell, a molten carbonate fuel cell, a solid electrolyte fuel cell, an alkaline fuel cell, or the like.

Further, the heat storage tank is not limited to being constituted by the raw fuel tank itself, but may be constituted by, for example, a part of the raw fuel tank.

[0031]

EXAMPLES Example 1 System 1 of the First Embodiment
A fuel cell cogeneration system was prepared from which the desulfurization unit was removed. Kerosene ... 196L. Fuel cell: 1kW solid polymer fuel cell for detached houses. The installation area of this fuel cell cogeneration system is
0.8 m ² . Further, assuming the power demand and heat demand of an average detached house, the overall efficiency when this system was operated was 61%.

(Example 2) In the first embodiment,
Specific conditions were as follows. Kerosene ... 180 L (sulfur concentration: 35 ppm). Desulfurizing agent unit: filled with 3 L of activated carbon. By operating this system, the temperature sensor in the raw fuel tank controls the circulating amount of water as the heat medium, and when the temperature in the raw fuel tank reaches 35 degrees, the kerosene supplied to the reformer Sulfur concentration is 1pp
m.

Example 3 In the second embodiment,
Specific conditions were as follows. Heat storage material: Adeka Thermo Top M35 (Asahi Denka Kogyo Co., Ltd.)
170 kg) The installation area of this fuel cell cogeneration system was 1.0 m ² . Further, as in the first embodiment, assuming the average power demand and heat demand of a detached house, the overall efficiency when this system was operated was 63%.

(Comparative Example) As shown in FIG. 5, a fuel cell cogeneration system 100 in which a hot water storage tank 101 was separately provided to store heat was manufactured. Hot water tank ... 200L. The installation area of this fuel cell cogeneration system was 1.9 m ² . Further, as in the first embodiment, assuming the average power demand and heat demand of a detached house, the overall efficiency when this system was operated was 62%.

From these Examples and Comparative Examples, it was confirmed that the total efficiency was hardly changed even if the raw fuel tank was used as a heat storage tank or a separate hot water storage tank was provided for storing heat. It is also found that the use of a desulfurizing agent reduces the sulfur concentration in kerosene to such an extent that corrosion of the raw fuel tank and catalyst poisoning can be prevented. Further, while covering the periphery of the raw fuel tank with a heat storage layer, forming irregularities on the inner wall surface of the raw fuel tank, and forming irregularities at a boundary portion between the heat storage layer and the tank, compared with other examples and comparative examples. It was confirmed that the overall efficiency was the best.

[0036]

As described above, according to the fuel cell cogeneration system of the present invention, the raw fuel tank is formed as a heat storage tank for storing waste heat of at least one of the reformer and the fuel cell. In addition, there is an effect that it can be installed even in an urban house where there is no room on the site.

[Brief description of the drawings]

FIG. 1 is a block diagram showing a fuel cell cogeneration system according to a first embodiment of the present invention.

FIG. 2 is a sectional view showing a raw fuel tank in the embodiment.

FIG. 3 is a block diagram showing a fuel cell cogeneration system according to a second embodiment of the present invention.

FIG. 4 is a cross-sectional view illustrating a raw fuel tank according to a modification of the present invention.

FIG. 5 is a block diagram showing a fuel cell cogeneration system according to a comparative example of the present invention.

[Description of Signs] 1 Fuel cell cogeneration system 2 Raw fuel tank 3 Reformer 4 Fuel cell 12 Inorganic salt (calcium chloride hexahydrate) as heat storage material 21 Kerosene as raw fuel 27 Desulfurizer unit

Claims (4)

[Claims] 1. A reformer generates a hydrogen-rich reformed gas from a raw fuel supplied from a raw fuel tank, and uses a hydrogen of the generated reformed gas as a fuel to generate electric power in a fuel cell. A fuel cell cogeneration system that recovers waste heat from a reformer and a fuel cell and uses the recovered waste heat as thermal energy, wherein at least a part of the raw fuel tank is a waste heat of at least one of the reformer and the fuel cell. A fuel cell cogeneration system characterized by using a waste heat stored in the heat storage tank. 2. The fuel cell cogeneration system according to claim 1, wherein a desulfurizing agent capable of removing sulfur compounds contained in the raw fuel is provided in the raw fuel tank. Fuel cell cogeneration system. 3. The fuel cell cogeneration system according to claim 1, wherein a heat storage material for storing waste heat stored in the raw fuel is provided around and / or inside the raw fuel tank. A fuel cell cogeneration system characterized in that: 4. The fuel cell cogeneration system according to claim 3, wherein irregularities are formed on an inner wall surface of the raw fuel tank.