JPH11264325A - Carbon dioxide recovery type power generation plant - Google Patents

Abstract

PROBLEM TO BE SOLVED: To prevent thermal deterioration of turbine blades by cooling the turbine blades by the use of recovered carbon dioxice and decreasing temperature of combustion gas to be supplied to a turbine. SOLUTION: This plant has a combustion means 1 for burning fuel by oxygen to generate combustion gas including carbon dioxide and moisture gas, a turgine generator means 40 for rotating blades of a gas turbine 4 by the use of the combustion gas generated by the combustion means 1 to generate power, and a cooling means 10 for cooling the rotational blades. The cooling means 10 has a condenser 6 which condenses exhaust gas after recovering exhaust heat to generate carbon dioxice and water, an exhaust heat recovery means 5 for evaporating the condensed water by the use of exhaust heat of the turbine generator means 40, and a feedback supplying passage 8 for supplying the generated steam to cool the rotational blades of the gas turbine 4 of the turbine generator means 40.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a power plant for recovering carbon dioxide, and more particularly, to recovering carbon dioxide condensed by a condenser and simultaneously cooling blades of turbine power generation means using water condensed. And a carbon dioxide recovery type power plant.

[0002]

2. Description of the Related Art FIG. 16 is a block diagram showing a system of a conventional carbon dioxide capture type gas turbine power plant.
In FIG. 16, a power plant includes a combustor 1 configured to burn fuel in the presence of oxygen, a fuel supply device 2 connected to the combustor 1 to supply the fuel,
An oxygen supply device 3 connected to the combustor 1 for supplying the oxygen, a gas turbine 4 driven by combustion gas burned in the combustor to discharge exhaust gas mainly containing carbon dioxide and moisture gas, Exhaust heat recovery boiler 5 connected to gas turbine 4 for recovering exhaust heat from the exhaust gas
A condenser 6 connected to the exhaust heat recovery boiler 5 to condense the moisture gas in the exhaust gas from the exhaust heat recovery boiler 5; And a compressor 7 for supplying to the combustor 1.

[0003] The carbon dioxide recovery type power plant having the above configuration is disclosed, for example, in Japanese Patent Application Laid-Open No. 3-145523 filed jointly by the present applicant. This publication discloses several thermal power plants related to a closed dual fluid gas turbine power generation structure. For example, in the thermal power plant according to the first embodiment shown in FIG. 1 of this publication, a condenser and a compressor as shown in FIG. 16 are shown, and between them, FIG. A water separation device and a carbon dioxide recovery and removal device whose illustration is omitted are provided. The collection and removal device has a suction pump P, a reservoir R and the like.

[0004]

However, according to the above-mentioned conventional carbon dioxide recovery type power plant, the carbon dioxide recovered after passing through the exhaust heat recovery boiler 5 and the condenser 6 is compressed by a compressor. To combustor 1,
Since the carbon dioxide is reused for combustion in the combustor 1, there is a problem that the combustion temperature of the combustion gas becomes considerably high and a high-temperature combustion gas is supplied to the gas turbine. If the combustion gas becomes hotter than expected, not only may the high-temperature combustion gas be directly sprayed on the rotor blades constituting the turbine, but also the high-temperature combustion gas There is a problem that the rotor blades of the turbine may be deteriorated due to the excessive supply.

The present invention has been made in order to solve the above-mentioned problems of the conventional power generation plant, and supplies the turbine to the turbine by cooling the turbine with cooling means using recovered carbon dioxide, water and the like. It is an object of the present invention to provide a carbon dioxide recovery type power generation plant capable of lowering the temperature of combustion gas to be discharged and preventing thermal deterioration of turbine blades.

[0006]

Means for Solving the Problems To solve the above problems, a carbon dioxide capture type power plant according to claim 1 is provided.
Combustion means for burning fuel using oxygen to generate a combustion gas containing at least carbon dioxide and moisture gas, and at least a rotating blade, using the combustion gas generated by the burning means with the rotating blade A turbine power generating means for rotating to generate electric power, an exhaust heat recovery means for generating steam using exhaust heat held by the exhaust gas after the combustion gas has been used, and an exhaust heat recovery means for Condensing means for condensing the recovered exhaust gas to generate carbon dioxide and water; and carbon dioxide which compresses a gas element mainly containing the carbon dioxide generated by the condensing means and supplies the gas element to the combustion means. Carbon recovery means, the condensing means for generating water from the exhaust gas, the exhaust heat recovery means for converting the water into steam by the exhaust heat of the turbine power generation means, and the exhaust heat recovery means. Is characterized in that it comprises a cooling means at least include a feedback supply passage, for supplying to the cooling of the rotor blades of the turbine power generator the steam generated by.

[0007] In a second aspect of the present invention, in the carbon dioxide recovery type power plant according to the first aspect, the cooling means uses steam of an exhaust heat recovery boiler as the exhaust heat recovery means as the combustion means. And a cooling path for supplying to the combustor.

In a third aspect of the present invention, in the carbon dioxide recovery type power plant according to the first aspect, the cooling means cools the rotating blades of the turbine power generation means by blowing air. I have.

A carbon dioxide recovery type power plant according to a fourth aspect of the present invention is the power plant according to the first aspect, further comprising a fuel reforming / decomposing means for reforming or decomposing the fuel into a hydrogen-containing gas. The combustion means burns the hydrogen-containing gas supplied from the fuel reforming / decomposing means using the oxygen.

According to a fifth aspect of the present invention, in the carbon dioxide recovery type power plant according to the fourth aspect, the fuel reforming / decomposing means is supplied from an exhaust heat recovery boiler as the exhaust heat recovery means. A fuel reformer that reforms the fuel into a hydrogen-containing gas by a reforming reaction using heat.

According to a sixth aspect of the present invention, in the carbon dioxide recovery type power plant according to the fourth aspect, the fuel decomposition / decomposition means is supplied from an exhaust heat recovery boiler as the exhaust heat recovery means. A fuel decomposition device that decomposes the fuel into a hydrogen-containing gas by a decomposition reaction using heat.

According to a seventh aspect of the present invention, in the carbon dioxide recovery type power plant according to the fourth aspect, the exhaust heat recovery means uses the exhaust heat from the turbine power generation means and water from the condensation means. The generated steam is supplied to the fuel reforming means.

[0013] Further, a carbon dioxide recovery type power plant according to claim 8 is the combustion plant according to claim 1, wherein the combustor burns fuel in the presence of oxygen.
A fuel supply device connected to supply fuel to the combustor, an oxygen supply device connected to supply oxygen to the combustor, and combustion gas from the combustor connected to the combustor. A driven turbine, an exhaust heat recovery boiler connected to a turbine that emits exhaust gas mainly composed of carbon dioxide and moisture gas, and an exhaust gas from the exhaust heat recovery boiler connected to the exhaust heat recovery boiler. A condenser for condensing the moisture gas, and a compressor connected to the condenser for compressing a gas element mainly composed of carbon dioxide, wherein the compressor is configured to supply the compressed carbon dioxide to the combustor. And a steam turbine connected to the exhaust heat recovery boiler and a condenser connected to the steam turbine and the exhaust heat recovery boiler via a pipeline. Constitute a closed cycle consisting of, and characterized by performing the blade cooling of the turbine with steam from the exhaust heat recovery boiler.

According to a ninth aspect of the present invention, in the carbon dioxide recovery type power plant according to the first aspect, a fuel reformer for converting a fuel into a hydrogen-containing gas and the fuel reformer in the presence of oxygen are provided. A combustor configured to burn the hydrogen-containing gas supplied from the combustor, an oxygen supply device connected to supply oxygen to the combustor, and a combustion gas from the combustor connected to the combustor. A driven turbine, an exhaust heat recovery boiler connected to a turbine that emits exhaust gas mainly composed of carbon dioxide and moisture gas,
A condenser connected to the exhaust heat recovery boiler for condensing moisture gas in exhaust gas from the exhaust heat recovery boiler, and a compressor connected to the condenser for compressing a gas element mainly composed of carbon dioxide, A compressor is connected to the combustor so as to supply compressed carbon dioxide to the combustor, and further includes a steam turbine connected to the exhaust heat recovery boiler, and a pipeline connected to the steam turbine and the exhaust heat recovery boiler. Characterized in that it constitutes a closed cycle consisting of a capacitor connected via

According to a tenth aspect of the present invention, there is provided a carbon dioxide recovery type power plant according to the first aspect, further comprising a fuel decomposer for converting a fuel into a hydrogen-containing gas and a fuel decomposer in the presence of oxygen. A combustor adapted to burn the supplied hydrogen-containing gas, an oxygen supply device connected to supply oxygen to the combustor, and a combustion gas driven from the combustor connected to the combustor A waste heat recovery boiler connected to a turbine that discharges exhaust gas mainly composed of carbon dioxide and moisture gas, and a moisture gas in exhaust gas from the waste heat recovery boiler connected to the waste heat recovery boiler. And a condenser to condense the
A compressor connected to the condenser for compressing a gas element mainly composed of carbon dioxide, wherein the compressor is connected to the combustor to supply compressed carbon dioxide to the combustor; A closed cycle including a steam turbine connected to the exhaust heat recovery boiler and a condenser connected to the steam turbine and the exhaust heat recovery boiler via a pipeline is provided.

According to an eleventh aspect of the present invention, there is provided a carbon dioxide recovery type power plant according to the first aspect, wherein a fuel is burned in the presence of oxygen, and fuel is supplied to the combustor. A fuel supply device connected to supply air to the combustor, an oxygen supply device connected to supply oxygen to the combustor, and a turbine driven by combustion gas from the combustor connected to the combustor. An exhaust heat recovery boiler connected to a turbine that discharges exhaust gas composed of carbon dioxide and moisture gas, and a condenser connected to the exhaust heat recovery boiler and condensing moisture gas in exhaust gas from the exhaust heat recovery boiler. The condenser is connected to the heat recovery steam generator to supply condensed water, and the heat recovery steam generator is connected to the combustor to supply superheated steam to the combustor. It is characterized by performing the blade cooling of the turbine with steam from the exhaust heat recovery boiler.

According to a twelfth aspect of the present invention, in the carbon dioxide recovery type power plant according to the first aspect, a fuel reformer for converting a fuel into a hydrogen-containing gas and the fuel reformer in the presence of oxygen are provided. A combustor configured to burn the hydrogen-containing gas supplied from the combustor, an oxygen supply device connected to supply oxygen to the combustor, and a combustion gas from the combustor connected to the combustor. A driven turbine, an exhaust heat recovery boiler connected to a turbine that emits exhaust gas mainly composed of carbon dioxide and moisture gas, and an exhaust gas from the exhaust heat recovery boiler connected to the exhaust heat recovery boiler. A condenser for condensing moisture gas,
The condenser is connected to the exhaust heat recovery boiler to supply condensed water, and the exhaust heat recovery boiler is connected to the combustor to supply superheated steam to the combustor.

According to a thirteenth aspect of the present invention, in the carbon dioxide recovery type power plant according to the first aspect, a combustor for burning fuel in the presence of oxygen, and a fuel is supplied to the combustor. A fuel supply device connected to supply air to the combustor, an oxygen supply device connected to supply oxygen to the combustor, and a turbine driven by combustion gas from the combustor connected to the combustor. An exhaust heat recovery boiler connected to a turbine that discharges exhaust gas composed of carbon dioxide and moisture gas, and a condenser connected to the exhaust heat recovery boiler and condensing moisture gas in exhaust gas from the exhaust heat recovery boiler. The condenser is connected to the heat recovery steam generator to supply condensed water, and the heat recovery steam generator is connected to the combustor to supply superheated steam to the combustor. It is characterized in that it further configured cycle composed of capacitors connected through the pipe and exhaust heat recovery boiler connected to a steam turbine to said steam turbine and said exhaust heat recovery boiler.

A carbon dioxide recovery type power plant according to a fourteenth aspect is the power generation plant according to the first aspect, wherein the fuel reformer converts fuel into a hydrogen-containing gas and the fuel reformer in the presence of oxygen. A combustor configured to burn the hydrogen-containing gas supplied from the combustor, an oxygen supply device connected to supply oxygen to the combustor, and a combustion gas from the combustor connected to the combustor. A driven turbine, an exhaust heat recovery boiler connected to a turbine that emits exhaust gas mainly composed of carbon dioxide and moisture gas, and an exhaust gas from the exhaust heat recovery boiler connected to the exhaust heat recovery boiler. A condenser for condensing moisture gas,
The condenser is connected to the exhaust heat recovery boiler to supply condensed water, the exhaust heat recovery boiler is connected to the combustor to supply superheated steam to the combustor, and further connected to the exhaust heat recovery boiler. A steam turbine and a condenser connected to the steam turbine and the exhaust heat recovery boiler via a pipeline.

According to a fifteenth aspect of the present invention, there is provided a carbon dioxide recovery type power plant according to the first aspect, wherein the fuel decomposer converts fuel into a hydrogen-containing gas and the fuel decomposer in the presence of oxygen. A combustor adapted to burn the supplied hydrogen-containing gas, an oxygen supply device connected to supply oxygen to the combustor, and a combustion gas driven from the combustor connected to the combustor A waste heat recovery boiler connected to a turbine that discharges exhaust gas mainly composed of carbon dioxide and moisture gas, and a moisture gas in exhaust gas from the waste heat recovery boiler connected to the waste heat recovery boiler. And a condenser to condense the
The condenser is connected to the exhaust heat recovery boiler to supply condensed water, the exhaust heat recovery boiler is connected to the combustor to supply superheated steam to the combustor, and further connected to the exhaust heat recovery boiler. A steam turbine and a condenser connected to the steam turbine and the exhaust heat recovery boiler via a pipeline.

Further, a carbon dioxide recovery type power plant according to claim 16 has a combustion means for generating a combustion gas using an oxidizing agent containing oxygen, and at least a rotating blade, wherein the rotating blade is controlled by the combustion means. Turbine power generation means for generating electric power by using the generated combustion gas, and reforming the fuel into a hydrogen-containing gas by using the exhaust heat held by the exhaust gas after the combustion gas is used. Fuel reforming / carbon dioxide separation means for separating generated carbon dioxide,
And a supply path for supplying the hydrogen-containing gas generated by the fuel reforming / carbon dioxide separation means to the combustion means.

A carbon dioxide recovery type power plant according to a seventeenth aspect is the power plant according to the sixteenth aspect, wherein the fuel reforming / carbon dioxide separating means includes a carbon dioxide selective permeable membrane. .

[0023] According to a eighteenth aspect of the present invention, in the carbon dioxide recovery type power plant according to the sixteenth aspect, the fuel reforming / carbon dioxide separating means includes a carbon dioxide adsorbent, It is characterized by being used for reproduction.

[0024]

BEST MODE FOR CARRYING OUT THE INVENTION Hereinafter, an embodiment of a carbon dioxide capture type power plant according to the present invention will be described in detail with reference to the accompanying drawings. First, a power plant according to a first embodiment as a basic concept of the present invention will be described with reference to FIG. In FIG. 1, the carbon dioxide recovery type power plant according to the first embodiment includes combustion means 1 for burning fuel using oxygen to generate a combustion gas containing at least carbon dioxide and moisture gas, and at least a rotor. A turbine generator means for rotating the gas turbine using the combustion gas generated by the combustion means to generate electric power, and a rotor for the gas turbine constituting the turbine power means Cooling means 10 for cooling the
It has.

The cooling means 10 includes an exhaust heat recovery means 5 for generating steam using exhaust heat held by the exhaust gas after the combustion gas is used, and an exhaust heat recovery means 5 for recovering the exhaust heat. Condensing means 6 for condensing the exhaust gas after being subjected to the heat treatment to produce carbon dioxide and water, and compressing a gas element mainly containing the carbon dioxide generated by the condensing means 6 by a compressor 7 or the like to perform the combustion. A carbon dioxide recovery means 7A to be supplied to the means 1; a condensing means 6 for generating water from the exhaust gas; a waste heat recovery means 5 for converting the water into steam by waste heat of the turbine power generation means 40; At least a return supply path 8 for supplying the steam generated by the recovery means 5 for cooling the rotating blades of the gas turbine 4 of the turbine power generation means 40.

In the power plant according to the first embodiment, the cooling means 10 cools the turbine blades of the power generating means 40 by the steam generated by using the exhaust heat by the above-described structure. Converts the carbon dioxide collected and compressed by the compressor 7 from the condensing means 6 into the combustion means 1
In addition to the supply to the turbine blades, the carbon dioxide may be supplied to the turbine blades of the turbine power generation means 40 via the cooling passage 9 to cool the turbine blades.
By providing the double cooling means in this way, the cooling effect can be further improved.

The carbon dioxide recovery type power plant according to the first embodiment having the above-described configuration is to fulfill the basic concept of the present invention, but the second embodiment as a more specific and specific embodiment of the present invention is described. Hereinafter, the fifteenth embodiment will be described in detail.

FIG. 2 is a block diagram showing a carbon dioxide capture type power plant according to a second embodiment of the present invention. 2, the same elements as those shown in FIGS. 1 and 16 are denoted by the same reference numerals, and redundant description will be omitted.
In the second embodiment, a part of the superheated steam obtained by supplying the condensed water from the condenser 6 as the condensing means to the exhaust heat recovery boiler 5 as the exhaust heat recovery means is supplied to the turbine 4 as a blade coolant. And blow-off cooling is performed.

Further, the remaining heated steam is supplied to the combustor 1 as combustion means, and is used for cooling the combustor. The steam supplied to the combustor 1 and the turbine 4 is supplied to the condenser 6
Is recovered as condensed water again. According to the above configuration, the compressed carbon dioxide that is necessary for cooling the turbine blades is not required, so that an effect peculiar to the second embodiment that the compressor loss can be reduced accordingly.

Next, a third embodiment of the present invention will be described. FIG. 3 is a block diagram showing a carbon dioxide capture type power plant according to a third embodiment of the present invention. In FIG. 3, the same elements as those in FIG. In the third embodiment, the fuel supply device 2 is connected to an exhaust heat recovery reformer / boiler 5 as exhaust heat recovery means.
And a part of the superheated steam obtained by supplying condensed water to the exhaust heat recovery / reformer / boiler 5 from the condenser 6 as a condensing means is used for the fuel reforming reaction. The section is supplied to the turbine 4 as a blade coolant to perform blow-off cooling. The rest is supplied to the combustor 1 as a combustion means, and a part of the remainder is used for cooling the combustor. The steam supplied to the combustor 1 and the turbine 4 is recovered again as condensed water by the condenser 6. The obtained reformed gas containing hydrogen is supplied to the combustor 1 and burned.

With the above configuration, the compressed carbon dioxide required for cooling the turbine blades is not required, so that the compressor loss can be reduced accordingly. Further, in the third embodiment, a part of the low-temperature heat energy of the exhaust gas of the turbine 4 can be converted into chemical energy by a reforming reaction and supplied to the combustor 1, so that the power generation efficiency can be improved. it can. Note that the compressor 7 may be configured to blow out carbon dioxide from the compressor 7 to the turbine 4 to cool the turbine 4, thereby improving the cooling capacity for the turbine 4. In the power plant according to the third embodiment, the switching valve 1 is provided in a path for returning the condensed water from the condenser 6 to the exhaust heat recovery boiler 5.
1 is provided so that a part of the condensed water can be discharged to the outside.

Next, a fourth embodiment of the present invention will be described. FIG. 4 is a block diagram showing a carbon dioxide capture power plant according to a fourth embodiment of the present invention. In FIG. 4, the same elements as those in FIG. In the fourth embodiment, the fuel supply device 2 is provided to the exhaust heat recovery decomposer / boiler 5 as the exhaust heat recovery means.
From the exhaust gas from the turbine 4 to generate a cracked gas containing hydrogen by a cracking reaction utilizing the heat of the exhaust gas. Further, a part of the superheated steam obtained by supplying the condensed water from the condenser 6 as a condenser to the exhaust heat recovery / reformer / boiler 5 is supplied to the turbine 4 as a blade coolant to perform blow-off cooling. The remainder is supplied to the combustor 1 as combustion means, and a part thereof is used for cooling the combustor 1. The steam supplied to the combustor 1 and the turbine 4 is supplied to the condenser 6
Is collected as condensed water. The obtained cracked gas containing hydrogen is supplied to the combustor 1 and burned.

According to the above configuration, the compressed carbon dioxide required for cooling the turbine blades is not required, so that the compressor loss can be reduced accordingly. Furthermore, in the fourth embodiment, part of the low-temperature heat energy held by the exhaust gas of the turbine 4 can be converted into chemical energy by a decomposition reaction and supplied to the combustor, so that the power generation efficiency can be improved. it can. In the fourth embodiment, the compressor 7 may be configured to blow out and cool carbon dioxide from the compressor 7 to the rotor blades of the turbine 4 so as to perform more efficient cooling.

Next, a fifth embodiment of the present invention will be described. FIG. 5 is a block diagram showing a carbon dioxide capture type power plant according to a fifth embodiment of the present invention. In FIG. 5, the same elements as those shown in FIG. 16 are denoted by the same reference numerals, and redundant description will be omitted. In the fifth embodiment, a part of the condensed water obtained by the condenser 6 as the condensing means is supplied to the exhaust heat recovery boiler 5 together with the condensed water from the condenser 42 connected to the steam turbine 41. A part of the obtained superheated steam is supplied to the turbine 4 as a blade cooling agent to perform blow-out cooling. A part is used for cooling the combustor 1 as a combustion means. The steam supplied to the combustor 1 and the turbine 4 is collected by the condenser 6 as condensed water. The remainder is supplied to the steam turbine 10,
Collected by the condenser 42.

According to the above configuration, the compressed carbon dioxide required for cooling the turbine blades is not required, so that the compressor loss can be reduced accordingly. Further, in this embodiment, the pure water required for the steam turbine can be supplied by the condensed water obtained by the condenser 6, and an external pure water supply source is unnecessary. In the fifth embodiment, the switching valve 11 is provided in the path for returning the condensed water from the condenser 6 to the exhaust heat recovery boiler 5 as in the third embodiment shown in FIG.
Is provided, and a condensed water recovery device 12 is provided on the near side of the reflux of the switching valve 11. In addition, a part of a path for supplying carbon dioxide from the condenser 6 to the compressor 7 is branched, and a carbon dioxide recovery / removal device 13 is provided at a leading end of the branch, and a part of carbon dioxide condensed by the condenser 6 is removed. The ratio of the carbon dioxide supplied to the compressor 7 is adjusted freely by removing it by the recovery and removal device 13. Reference numeral 43 denotes an adjustment valve provided in a path from the condenser 42 to the heat recovery steam reformer / boiler 5.

Next, a sixth embodiment of the present invention will be described. FIG. 6 is a block diagram showing a carbon dioxide capture type power plant according to a sixth embodiment of the present invention. In FIG. 6, the same elements as those in the fifth embodiment shown in FIG. The description of the operation will be omitted. In the sixth embodiment, fuel is supplied from the fuel supply device 2 to the waste heat recovery reformer / boiler 5 as waste heat recovery means, and the condenser 6
Is combined with the condensed water from the condenser 42 connected to the steam turbine 41, and then the condensed water is supplied to the exhaust heat recovery / reformer / boiler 5 to obtain one of the superheated steam obtained. The part is used for a fuel reforming reaction, and another part is supplied to the turbine 4 as a blade coolant to perform blow-off cooling. A part is used for cooling the combustor 1 as a combustion means. The steam supplied to the combustor 1 and the turbine 4 is collected by the condenser 6 as condensed water. The remainder is supplied to the steam turbine 41 and collected by the condenser 42.

According to the above configuration, the compressed carbon dioxide required for cooling the turbine blades is not required, so that the compressor loss can be reduced accordingly. Further, in the sixth embodiment, the pure water required for the steam turbine 41 can be supplied by the condensed water obtained by the condenser 6, and an external pure water supply source is unnecessary. Further, in the sixth embodiment, a part of the low-temperature heat energy of the exhaust gas of the turbine 4 can be converted into chemical energy by a reforming reaction and supplied to the combustor 1 as a combustion means, so that the power generation efficiency is improved. Can be done.

Next, a seventh embodiment of the present invention will be described. FIG. 7 is a block diagram showing a configuration of a carbon dioxide capture type power plant according to a seventh embodiment of the present invention.
In FIG. 6, the same elements as those of the sixth embodiment shown in FIG.
In the seventh embodiment, the fuel is supplied from the fuel supply device 2 to the exhaust heat recovery decomposer / boiler 5 as the exhaust heat recovery means, and a cracked gas containing hydrogen is generated. Combustion is performed. Further, a part of the condensed water obtained by the condenser 6 is combined with the condensed water from the condenser 42 connected to the steam turbine 41, and then the condensed water is supplied to the exhaust heat recovery decomposer / boiler 5 to obtain the condensed water. Part of the superheated steam is used for the fuel reforming reaction, and another part is
Is supplied as a blade cooling agent to perform blow-off cooling. A part is used for combustor cooling. The steam supplied to the combustor 1 and the turbine 4 is collected by the condenser 6 as condensed water. The remainder is supplied to the steam turbine 41 and collected by the condenser 42.

According to the above configuration, the compressed carbon dioxide required for cooling the turbine blades is not required, so that the compressor loss can be reduced accordingly. Further, in this embodiment, the pure water required for the steam turbine can be supplied by the condensed water obtained by the condenser 6, and an external pure water supply source is unnecessary. Furthermore, in the seventh embodiment, part of the low-temperature heat energy of the exhaust gas of the turbine 4 can be converted into chemical energy by a decomposition reaction and supplied to the combustor, so that the power generation efficiency can be improved.

Next, an eighth embodiment of the present invention will be described. FIG. 8 is a block diagram showing a configuration of a carbon dioxide capture type power plant according to an eighth embodiment of the present invention.
In FIG. 2, the same components as those of the second embodiment shown in FIG.
In the eighth embodiment, a part of the superheated steam obtained by supplying the condensed water from the condenser 6 as the condensing means to the exhaust heat recovery boiler 5 as the exhaust heat recovery means is supplied to the turbine 4 as a blade coolant. Then, blow-off cooling is performed. The remainder is supplied to the combustor 1 as a combustion means, and a part thereof is used for cooling the combustor 1. Combustor 1 and turbine 4
Supplied to the condenser 6 is collected by the condenser 6 as condensed water.

With the above configuration, the compressed carbon dioxide required for cooling the turbine blades is not required, so that the compressor loss can be reduced accordingly. Further, in the present embodiment, only the fuel from the fuel supply device 2, the oxygen from the oxygen supply device 3 and the superheated steam from the exhaust heat recovery boiler 5 are supplied to the combustor 1 as well. Since the compressor 7 becomes unnecessary, compressor loss can be eliminated.

Next, a ninth embodiment of the present invention will be described. FIG. 9 is a block diagram showing a configuration of a carbon dioxide capture type power generation system according to a ninth embodiment of the present invention.
In FIG. 8, the same elements as those of the eighth embodiment shown in FIG.
In the ninth embodiment, the exhaust heat recovery reformer / boiler 5
A part of the superheated steam obtained by supplying fuel from the fuel supply device 2 to the condenser 6 and supplying condensed water from the condenser 6 as condensing means to the exhaust heat recovery boiler 5 as exhaust heat recovery means is used for the reforming reaction. Then, another part is supplied as a blade coolant to the turbine 4 to perform blow-off cooling. The remainder is supplied to the combustor 1 as combustion means, and a part thereof is used for combustor cooling. The steam supplied to the combustor 1 and the turbine 4 is collected by the condenser 6 as condensed water. A switching valve 11 is provided between the condenser 6 and the exhaust heat reformer / boiler 5.

According to the above configuration, the compressed carbon dioxide required for cooling the turbine blades is not required, so that the compressor loss can be reduced accordingly. Further, in this embodiment, since only the oxygen from the oxygen supply device 3 and the superheated steam and the reformed gas from the exhaust heat recovery boiler are also supplied to the combustor 1, the compressor 7 in FIG. Can be eliminated. Furthermore, in the ninth embodiment, part of the low-temperature heat energy of the exhaust gas of the turbine 4 can be converted into chemical energy by a reforming reaction and supplied to the combustor, so that the power generation efficiency can be improved. .

Next, a tenth embodiment of the present invention will be described. FIG. 10 is a block diagram showing the configuration of a carbon dioxide capture power plant according to a tenth embodiment of the present invention. In FIG. 10, the same elements as those of the ninth embodiment shown in FIG. The reference numerals are given and the duplicate description is omitted. In the tenth embodiment, fuel is supplied from the fuel supply device 2 to the exhaust heat recovery / decomposer / boiler 5 to obtain a decomposed gas containing hydrogen. In addition, a part of the superheated steam obtained by supplying the condensed water from the condenser 6 to the exhaust heat recovery boiler 5 is supplied to the turbine 4 as a blade cooling agent to perform blow-out cooling. The remainder is supplied to the combustor 1 and a part thereof is used for combustor cooling. The steam supplied to the combustor 1 and the turbine 4 is collected by the condenser 6 as condensed water.

According to the above configuration, the compressed carbon dioxide required for cooling the turbine blades is not required, so that the compressor loss can be reduced accordingly. Further, in this embodiment, since only the oxygen from the oxygen supply device 3 and the superheated steam and the cracked gas from the exhaust heat recovery boiler are supplied to the combustor 1, the compressor 7 in FIG. be able to. Further, in this embodiment, a part of the low-temperature heat energy of the exhaust gas of the turbine 4 can be converted into chemical energy by a decomposition reaction and supplied to the combustor, so that the power generation efficiency can be improved.

Next, an eleventh embodiment of the present invention will be described. FIG. 11 is a block diagram showing a configuration of a carbon dioxide capture type power plant according to an eleventh embodiment of the present invention. In FIG. 11, the same elements as those in the second embodiment shown in FIG. Therefore, duplicate description will be omitted.
In the eleventh embodiment, the superheated steam obtained by supplying a part of the condensed water obtained by the condenser 6 to the exhaust heat recovery boiler 5 together with the condensed water from the condenser 42 connected to the steam turbine 41 Is supplied to the turbine 4 as a blade coolant to perform blow-off cooling. A part is used for cooling the combustor 1 as a combustion means. The steam supplied to the combustor 1 and the turbine 4 is collected by the condenser 6 as condensed water. The remainder is supplied to the steam turbine 41,
Collected by the condenser 42. The condenser 6 has a deaerator 14 for removing carbon dioxide dissolved gas contained in the condensed water.
And a switching valve 15 for switching the condensed water from which the carbon dioxide has been removed by the deaerator 14 to reflux. The carbon dioxide separated by the deaerator 14 is supplied to the condenser 6.
To a path leading to a carbon dioxide recovery and removal device 13 from the air conditioner.

According to the above configuration, the compressed carbon dioxide required for cooling the turbine blades is not required, so that the loss of the compressor can be reduced accordingly. Further, in the eleventh embodiment, only the fuel from the fuel supply device 2, the oxygen from the oxygen supply device 3 and the superheated steam from the exhaust heat recovery boiler are supplied to the combustor 1 as well.
Becomes unnecessary, and compressor loss can be eliminated. Further, in the eleventh embodiment, the pure water required for the steam turbine 41 can be supplied by the condensed water obtained by the condenser 6, and an external pure water supply source is unnecessary.

Next, a twelfth embodiment of the present invention will be described. FIG. 12 is a block diagram showing a configuration of a carbon dioxide capture power plant according to a twelfth embodiment of the present invention. In FIG. 12, the same elements as those of the eleventh embodiment in FIG. Therefore, duplicate description will be omitted. In the twelfth embodiment, fuel is supplied from the fuel supply device 2 to the exhaust heat recovery reformer / boiler 5 as exhaust heat recovery means, and a part of the condensed water obtained by the condenser 6 is removed.
A part of the superheated steam obtained by supplying the condensed water to the exhaust heat recovery / reformer / boiler 5 together with the condensed water from the condenser 42 connected to the steam turbine 41 is used for the fuel reforming reaction. Supply another part to the turbine 4 as blade cooling agent,
Blow cooling is performed. A part is used for cooling the combustor 1 as a combustion means. The steam supplied to the combustor 1 and the turbine 4 is collected by the condenser 6 as condensed water. The remainder is supplied to the steam turbine 41 and the condenser 4
Collected in 2.

According to the above configuration, the compressed carbon dioxide required for cooling the turbine blades is not required, so that the loss of the compressor can be reduced correspondingly. Further, in this embodiment, since only the oxygen from the oxygen supply device 3 and the superheated steam and the reformed gas from the exhaust heat recovery boiler are also supplied to the combustor 1, the compressor 7 in FIG. 2 becomes unnecessary, and the compressor loss is eliminated. be able to. Further, in the twelfth embodiment, pure water required for the steam turbine can be supplied by the condensed water obtained by the condenser 6, and an external pure water supply source is unnecessary. Furthermore, in this embodiment, a part of the low-temperature heat energy of the exhaust gas of the turbine 4 can be converted into chemical energy by a reforming reaction and supplied to the combustor, so that the power generation efficiency can be improved.

Next, a thirteenth embodiment of the present invention will be described. FIG. 13 is a block diagram illustrating a configuration of a carbon dioxide capture power plant according to a thirteenth embodiment of the present invention. 13, the same elements as those of the twelfth embodiment in FIG. 12 are denoted by the same reference numerals, and the duplicate description will be omitted. In the present invention, the fuel is supplied from the fuel supply device 2 to the exhaust heat recovery decomposer / boiler 5 as the exhaust heat recovery means to generate a decomposition gas containing hydrogen, and is burned in the combustor 1 as the combustion means. A part of the condensed water obtained by the condenser 6 is combined with the condensed water from the condenser 42 connected to the steam turbine 41, and then the condensed water is supplied to the exhaust heat recovery / reformer / boiler 5 to obtain the condensed water. A part of the superheated steam is used for a fuel reforming reaction, and another part is supplied to the turbine 4 as a blade coolant to perform blow-out cooling. A part is used for cooling the combustor 1. The steam supplied to the combustor 1 and the turbine 4 is collected by the condenser 6 as condensed water. The remainder is supplied to the steam turbine 41 and the condenser 4
Collected in 2.

According to the above configuration, the compressed carbon dioxide necessary for cooling the turbine blades is not required, so that the loss of the compressor can be reduced accordingly. Further, in the thirteenth embodiment, only the oxygen from the oxygen supply device 3 and the superheated steam and the cracked gas from the exhaust heat recovery boiler are also supplied to the combustor 1, so that the compressor 7 in FIG. Loss can be eliminated. Further, in the thirteenth embodiment, the pure water required for the steam turbine can be supplied by the condensed water obtained by the condenser 6, and an external pure water supply source becomes unnecessary. Furthermore, in the thirteenth embodiment, part of the low-temperature heat energy of the exhaust gas of the turbine 4 can be converted into chemical energy by a decomposition reaction and supplied to the combustor, so that the power generation efficiency can be further improved.

FIG. 14 is a block diagram showing a carbon dioxide capture type power plant according to a fourteenth embodiment of the present invention.
In FIG. 14, a part of the steam generated in the exhaust heat recovery boiler 5 is supplied to the fuel reforming / carbon dioxide separation means 101 together with methane as fuel. Methane and steam are reformed /
It is converted into hydrogen and carbon dioxide by the following reforming reaction CH ₄ + 2H ₂ O → CO ₂ + 4H _{2 in the} carbon dioxide separating means 101. The generated carbon dioxide is absorbed by the carbon dioxide absorbent. The remaining hydrogen-containing gas is burned in the combustor 1 with the air supplied from the compressor 7 to drive the turbine 4. On the other hand, the carbon dioxide adsorbent that has adsorbed carbon dioxide moves to the adsorbent regenerator 102, releases carbon dioxide, and returns to the fuel reforming / carbon dioxide separation means 101. The carbon dioxide released by the adsorbent regenerator 102 is liquefied by a carbon dioxide liquefaction device 103 and stored in the ocean.

According to the above configuration, since carbon dioxide is reformed and recovered from the high-pressure reformed gas containing carbon dioxide at a high concentration, it has the following features. The volume of fluid that needs to be treated is 1/10 to 1/80, and the pressure loss is 1/20 to 1 /
It can be reduced to 100. Since the gas that is burned is mainly hydrogen, it is not necessary to recover carbon dioxide from the flue gas. Therefore, air can be used instead of oxygen as the oxidizing agent. At low temperatures, the methane reforming reaction proceeds above the equilibrium concentration.

Lastly, a carbon dioxide capture type power plant according to a fifteenth embodiment of the present invention will be described. FIG.
FIG. 26 is a block diagram illustrating a configuration of a carbon dioxide capture power plant according to a fifteenth embodiment of the present invention. In FIG. 15, a part of the steam generated in the exhaust heat recovery boiler 5 is combined with methane as a fuel in the fuel reforming / carbon dioxide separation means 101.
Supply to Methane and water vapor are converted into hydrogen and carbon dioxide in the fuel reforming / carbon dioxide separation means 101 by the following reforming reaction CH ₄ + 2H ₂ O → CO ₂ + 4H ₂ . The generated carbon dioxide passes through the carbon dioxide selective permeable membrane 104 and moves to the carbon dioxide liquefaction device 103. Carbon dioxide liquefaction device 10
In 3 the carbon dioxide is liquefied and stored in the ocean.

According to the above configuration, since carbon dioxide is reformed and recovered from the high-pressure reformed gas containing carbon dioxide at a high concentration, it has the following features. The volume of fluid that needs to be treated is 1/10 to 1/80, and the pressure loss is 1/20 to 1 /
It can be reduced to 100. Since what is burned is a gas mainly composed of hydrogen, it is not necessary to recover carbon dioxide from the combustion exhaust gas. Therefore, air can be used instead of oxygen as the oxidizing agent. At low temperatures, the methane reforming reaction proceeds above the equilibrium concentration.

[0056]

As described above in detail, according to the carbon dioxide recovery type power generation system according to the present invention, the blade of the gas turbine constituting the power generation means by the cooling means utilizing the recovered carbon dioxide, water and the like. So that it cools
By lowering the temperature of the combustion gas supplied to the turbine, thermal deterioration of the turbine blade can be prevented. Further, when the turbine blades are cooled only by the condensed water supplied from the condensing means constituting the cooling means, the compressor for generating the compressed carbon dioxide gas is not required, so that the compressor loss can be reduced. is there.

[Brief description of the drawings]

FIG. 1 is a block diagram showing a configuration of a carbon dioxide capture type power plant according to a first embodiment as a basic concept of the present invention.

FIG. 2 is a block diagram showing a configuration of a carbon dioxide capture type power plant according to a second embodiment of the present invention.

FIG. 3 is a block diagram showing a configuration of a carbon dioxide capture type power plant according to a third embodiment of the present invention.

FIG. 4 is a block diagram showing a configuration of a carbon dioxide capture type power plant according to a fourth embodiment of the present invention.

FIG. 5 is a block diagram showing a configuration of a carbon dioxide capture type power plant according to a fifth embodiment of the present invention.

FIG. 6 is a block diagram illustrating a configuration of a carbon dioxide capture power plant according to a sixth embodiment of the present invention.

FIG. 7 is a block diagram showing a configuration of a carbon dioxide capture type power plant according to a seventh embodiment of the present invention.

FIG. 8 is a block diagram showing a configuration of a carbon dioxide capture type power plant according to an eighth embodiment of the present invention.

FIG. 9 is a block diagram showing a configuration of a carbon dioxide capture power plant according to a ninth embodiment of the present invention.

FIG. 10 is a block diagram showing a configuration of a carbon dioxide capture type power plant according to a tenth embodiment of the present invention.

FIG. 11 is a block diagram showing a configuration of a carbon dioxide capture power plant according to an eleventh embodiment of the present invention.

FIG. 12 is a block diagram showing a configuration of a carbon dioxide capture power plant according to a twelfth embodiment of the present invention.

FIG. 13 is a block diagram showing a configuration of a carbon dioxide capture type power plant according to a thirteenth embodiment of the present invention.

FIG. 14 is a block diagram showing a configuration of a carbon dioxide capture type power plant according to a fourteenth embodiment of the present invention.

FIG. 15 is a block diagram showing a configuration of a carbon dioxide capture type power plant according to a fifteenth embodiment of the present invention.

FIG. 16 is a block diagram showing a configuration of a conventional carbon dioxide capture power plant.

[Explanation of symbols]

DESCRIPTION OF SYMBOLS 1 Combustion means (combustor) 4 Turbine 40 Turbine power generation means 41 Steam turbine 5 Exhaust heat recovery means (Exhaust heat recovery boiler, Exhaust heat recovery decomposer /
Boiler, waste heat recovery reformer boiler) 6 Condensing means (condenser) 7A Carbon dioxide collecting means 7 Compressor 8 (for cooling water) feedback supply path 9 Cooling carbon dioxide supply path 10 Cooling means 101 Fuel reforming / carbon dioxide Separation means 103 Carbon dioxide liquefaction device 104 Carbon dioxide selective permeation membrane

──────────────────────────────────────────────────続 き Continued on the front page (51) Int.Cl. ⁶ Identification code FI F02C 3/34 F02C 3/34 6/00 6/00 ED 7/18 7/18 A 7/22 7/22 D

Claims (18)

[Claims] 1. A combustion means for burning a fuel using oxygen to generate a combustion gas containing at least carbon dioxide and moisture gas; and at least a rotating blade, wherein said rotating blade is formed by said burning means. A turbine power generation unit that generates electric power by rotating using combustion gas; an exhaust heat recovery unit that generates steam using exhaust heat held by the exhaust gas after the combustion gas is used; Condensing means for condensing the exhaust gas after exhaust heat is recovered by the means to generate carbon dioxide and water; and compressing a gas element mainly containing the carbon dioxide generated by the condensing means to perform the combustion. Means for recovering carbon dioxide to be supplied to the means, the condensing means for producing water from the exhaust gas, the exhaust heat collecting means for converting the water into steam by the exhaust heat of the turbine power generating means, Carbon dioxide capture power generation plant comprising a cooling means, a containing feedback supply path for supplying, at least for the cooling of the rotor blade of the steam generated by the exhaust heat recovery means the turbine generator unit. 2. The cooling device according to claim 1, wherein said cooling means further comprises a cooling passage for supplying steam of the exhaust heat recovery boiler as said exhaust heat recovery means to a combustor as said combustion means. Carbon dioxide capture power plant. 3. The carbon dioxide recovery type power plant according to claim 1, wherein said cooling means cools said rotor blades of said turbine power generation means by blow-off cooling. 4. A fuel reforming / decomposing means for reforming or decomposing the fuel into a hydrogen-containing gas, wherein the combustion means uses the oxygen to supply the hydrogen supplied from the fuel reforming / decomposing means. The carbon dioxide recovery type power plant according to claim 1, wherein the contained gas is burned. 5. The fuel reforming / decomposing means for reforming the fuel into a hydrogen-containing gas by a reforming reaction using heat supplied from an exhaust heat recovery boiler as the exhaust heat recovery means. 5. The apparatus according to claim 4, wherein the apparatus is constituted by a vessel.
2. A carbon dioxide capture power plant according to item 1. 6. The fuel decomposing / decomposing means comprises a fuel decomposer which decomposes the fuel into a hydrogen-containing gas by a decomposition reaction using heat supplied from an exhaust heat recovery boiler as the exhaust heat recovery means. 5. The method according to claim 4, wherein
2. A carbon dioxide capture power plant according to item 1. 7. The fuel reforming means according to claim 4, wherein said exhaust heat recovery means supplies steam generated by exhaust heat from said turbine power generation means and water from said condensing means to said fuel reforming means. The carbon dioxide capture type power plant according to the above. 8. A combustor adapted to burn fuel in the presence of oxygen, a fuel supply connected to supply fuel to said combustor, and connected to supply oxygen to said combustor. An oxygen supply device, a turbine driven by combustion gas from the combustor connected to the combustor, and an exhaust heat recovery boiler connected to a turbine that emits exhaust gas mainly composed of carbon dioxide and moisture gas. A condenser connected to the exhaust heat recovery boiler for condensing moisture gas in exhaust gas from the exhaust heat recovery boiler;
A compressor connected to the condenser for compressing a gas element mainly composed of carbon dioxide, wherein the compressor is connected to the combustor so as to supply compressed carbon dioxide to the combustor. Further, a closed cycle is constituted by a steam turbine connected to the exhaust heat recovery boiler and a condenser connected to the steam turbine and the exhaust heat recovery boiler via a pipeline, and the cooling of the rotor blades of the turbine is performed. The carbon dioxide recovery type power plant according to claim 1, wherein the power generation is performed using steam from an exhaust heat recovery boiler. 9. A fuel reformer for converting fuel into a hydrogen-containing gas, a combustor for burning a hydrogen-containing gas supplied from the fuel reformer in the presence of oxygen, and supplying oxygen to the combustor. An oxygen supply device, a turbine driven by combustion gas from the combustor connected to the combustor, and an exhaust gas connected to a turbine for discharging exhaust gas mainly composed of carbon dioxide and moisture gas. A heat recovery boiler, a condenser connected to the waste heat recovery boiler for condensing moisture gas in exhaust gas from the waste heat recovery boiler, and a compressor connected to the condenser for compressing a gas element mainly composed of carbon dioxide And the compressor is connected to the combustor so as to supply compressed carbon dioxide to the combustor, and further connected to the exhaust heat recovery boiler. Carbon dioxide capture power generation plant according to claim 1, characterized in that the steam turbine constituting a closed cycle consisting of capacitors connected via line to the steam turbine and the exhaust heat recovery boiler has. 10. A fuel decomposer for converting fuel to a hydrogen-containing gas, a combustor for burning the hydrogen-containing gas supplied from the fuel decomposer in the presence of oxygen, and supplying oxygen to the combustor. An oxygen supply device connected to the combustor, a turbine driven by combustion gas from the combustor connected to the combustor, and a waste heat recovery device connected to a turbine for discharging exhaust gas mainly composed of carbon dioxide and moisture gas A boiler, a condenser connected to the exhaust heat recovery boiler and condensing moisture gas in exhaust gas from the exhaust heat recovery boiler, and a compressor connected to the condenser and compressing a gas element mainly composed of carbon dioxide, With
The compressor is connected to the combustor so as to supply compressed carbon dioxide to the combustor, and further includes a steam turbine connected to the exhaust heat recovery boiler, and a pipe connected to the steam turbine and the exhaust heat recovery boiler. The carbon dioxide capture power plant according to claim 1, wherein the power plant forms a closed cycle including a condenser connected via a road. 11. A combustor adapted to burn fuel in the presence of oxygen, a fuel supply connected to supply fuel to said combustor, and connected to supply oxygen to said combustor. An oxygen supply device, a turbine driven by combustion gas from the combustor connected to the combustor, and an exhaust heat recovery boiler connected to a turbine that emits exhaust gas mainly composed of carbon dioxide and moisture gas. A condenser connected to the exhaust heat recovery boiler for condensing moisture gas in exhaust gas from the exhaust heat recovery boiler;
A compressor connected to the exhaust heat recovery boiler to supply condensed water and compressing a gas element mainly composed of carbon dioxide; and the exhaust heat recovery boiler supplies superheated steam to the combustor. 2. The power plant according to claim 1, wherein the power is connected to the combustor, and cooling of the rotor of the turbine is performed by steam from the heat recovery steam generator. 3. 12. A fuel reformer for converting fuel into a hydrogen-containing gas, a combustor for burning the hydrogen-containing gas supplied from the fuel reformer in the presence of oxygen, and supplying oxygen to the combustor. An oxygen supply device, a turbine driven by combustion gas from the combustor connected to the combustor, and an exhaust gas connected to a turbine for discharging exhaust gas mainly composed of carbon dioxide and moisture gas. A heat recovery boiler, and a condenser connected to the waste heat recovery boiler for condensing moisture gas in exhaust gas from the waste heat recovery boiler, wherein the condenser is configured to supply condensed water to the waste heat recovery boiler. The carbon dioxide recovery type according to claim 1, wherein the exhaust heat recovery boiler is connected to the combustor so as to supply superheated steam to the combustor. Power plant. 13. A combustor adapted to burn fuel in the presence of oxygen, a fuel supply connected to supply fuel to said combustor, and connected to supply oxygen to said combustor. An oxygen supply device, a turbine driven by combustion gas from the combustor connected to the combustor, and an exhaust heat recovery boiler connected to a turbine that emits exhaust gas mainly composed of carbon dioxide and moisture gas. A condenser connected to the exhaust heat recovery boiler to condense moisture gas in exhaust gas from the exhaust heat recovery boiler; and the condenser is connected to the exhaust heat recovery boiler so as to supply condensed water. A heat recovery boiler is connected to the combustor to supply superheated steam to the combustor;
2. The dioxide according to claim 1, further comprising a cycle including a steam turbine connected to the heat recovery steam generator and a condenser connected to the steam turbine and the heat recovery steam generator via a pipeline. Carbon recovery power plant. 14. A fuel reformer for converting a fuel into a hydrogen-containing gas, a combustor for burning a hydrogen-containing gas supplied from the fuel reformer in the presence of oxygen, and An oxygen supply device connected to supply oxygen, a turbine driven by combustion gas from the combustor connected to the combustor, and a turbine that discharges exhaust gas mainly composed of carbon dioxide and moisture gas. A waste heat recovery boiler connected thereto, a condenser connected to the waste heat recovery boiler for condensing moisture gas in exhaust gas from the waste heat recovery boiler, and the condenser recovering the waste heat recovery so as to supply condensed water. A steam turbine connected to the boiler, the exhaust heat recovery boiler connected to the combustor to supply superheated steam to the combustor, and further connected to the exhaust heat recovery boiler Carbon dioxide capture power generation plant according to claim 1, characterized in that to constitute a cycle comprising a capacitor connected via line to the steam turbine and the exhaust heat recovery boiler. 15. A fuel decomposer for converting a fuel into a hydrogen-containing gas, a combustor for burning a hydrogen-containing gas supplied from the fuel decomposer in the presence of oxygen, and supplying oxygen to the combustor. An oxygen supply device connected to supply; a turbine driven by combustion gas from the combustor connected to the combustor; and a turbine that discharges exhaust gas mainly composed of carbon dioxide and moisture gas. A waste heat recovery boiler, a condenser connected to the waste heat recovery boiler, for condensing moisture gas in exhaust gas from the waste heat recovery boiler, and the condenser connected to the waste heat recovery boiler to supply condensed water. The exhaust heat recovery boiler is connected to the combustor so as to supply superheated steam to the combustor, and further includes a steam turbine connected to the exhaust heat recovery boiler and the steam turbine. Turbine and carbon dioxide capture power generation plant according to claim 1, characterized in that to constitute a cycle comprising a capacitor connected via line to the exhaust heat recovery boiler. 16. A combustion means for generating a combustion gas using an oxidant containing oxygen, and at least a rotor, wherein the rotor generates electric power by using the combustion gas generated by the combustion means. Turbine power generation means, and fuel reforming for reforming fuel into a hydrogen-containing gas using exhaust heat retained by the exhaust gas after the combustion gas has been used and simultaneously separating carbon dioxide generated by the reforming / carbon dioxide A carbon dioxide recovery type power plant comprising: a separation unit; and a supply path for supplying a hydrogen-containing gas generated by the fuel reforming / carbon dioxide separation unit to the combustion unit. 17. The fuel reforming / carbon dioxide separating means,
The carbon dioxide recovery type power plant according to claim 16, further comprising a carbon dioxide selective permeable membrane. 18. The fuel reforming / carbon dioxide separating means,
17. The power plant according to claim 16, further comprising a carbon dioxide adsorbent, wherein the carbon dioxide adsorbent is reused.