JP3504121B2 - Thermoelectric generation system - Google Patents

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a thermoelectric power generation system using a thermoelectric material that converts heat into electric energy.

[0002]

2. Description of the Related Art In recent years, problems such as energy saving and clean energy have become important due to environmental problems such as global warming. Therefore, thermoelectric power generation using the so-called Seebeck effect, which converts the temperature difference between the high temperature source and the low temperature source into electric energy, does not generate exhaust gas such as carbon dioxide gas and can be easily installed anywhere, so it does not adversely affect the environment. It is receiving attention as power generation.

The performance of the thermoelectric material is determined by the combination of three characteristics of the thermoelectromotive force, electric resistance and thermal conductivity of the substance, and the thermoelectric performance index is represented by the following mathematical formula (1).

Z = α ² / (ρ · κ) (1) where Z is the thermoelectric figure of merit (K ⁻¹ ), and α is the thermoelectromotive force (μ
V / K), ρ is electrical resistivity (Ω · cm), and κ is thermal conductivity (W / cm · K).

In practice, a value ZT which is made dimensionless by multiplying Z by a temperature difference (ΔT) is used for performance evaluation of thermoelectric materials. As can be seen from the above formula (1), in order to achieve high performance, it is necessary to have both high thermoelectromotive force, low electric resistance, and low thermal conductivity, and further, there is a large temperature difference for power generation. That leads to high efficiency.

Materials that are generally considered to be used as thermoelectric materials are Si, Ge, In, Sb, Te, and Bi.
The main material is a semiconductor material mainly containing such elements. However, semiconductor materials have higher electric resistance than metals, and generally have poor oxidation resistance. Therefore, there is a problem that it is not suitable for power generation using a high temperature heat source.

On the other hand, a metal-based thermoelectric material typified by a thermocouple material has small electric resistance and excellent oxidation resistance, but has a problem that it has a small thermoelectromotive force and a large thermal conductivity. Since the thermoelectromotive force α can be squared to the thermoelectric figure of merit as shown in the above-mentioned mathematical expression (1), the small thermoelectromotive force was the biggest problem in practical use of metal-based materials. .

As described above, since both semiconductor materials and metallic materials have problems in their characteristics, it is the current situation that highly efficient thermoelectric materials have not yet been obtained. .

On the other hand, it is necessary to secure surplus high-temperature and low-temperature heat sources in order to perform highly efficient and efficient power generation. From this point of view, it has been noted in recent years that the waste heat of a refuse incinerator or the like is used, but in this case, since there is no cooling source, only a material having a low thermal conductivity and a semiconductor can be applied. Further, since the high temperature oxidation resistance and high temperature strength of the material are not sufficient, there is a problem that the temperature on the high temperature side cannot be increased. In addition, the use of metallic materials with excellent high-temperature stability by forced cooling with water, air, etc. was also examined.However, conventional metallic materials have a low thermoelectromotive force and can produce a large output. In addition to the characteristics of the thermoelectric material, there is a problem that the high temperature strength is low.

[0010]

SUMMARY OF THE INVENTION The present invention has been made to solve the problems relating to these current thermoelectric materials and thermoelectric power generation. That is, the present invention is the power generation efficiency
The object is to provide a high thermoelectric power generation system.

[0011]

In order to solve the above problems, the present invention provides a metal matrix and the metal matrix.
And a dispersion material dispersed in the cast, the dispersion material,
The metal matrix is composed of different materials.
The waste heat of the gas turbine and the liquid that becomes the fuel
It is characterized by generating electric power by utilizing the temperature difference from chemical natural gas.
To provide a thermoelectric power generation system .

[0012]

[0013]

The present invention will be described in detail below. The thermoelectric material of the present invention comprises a matrix of a metal thermoelectric material in which a substance different from the matrix is dispersed. Since the two-phase mixed structure is used as described above, the characteristics of the metal thermoelectric material can be improved, and the low thermoelectromotive force and the high thermal conductivity, which are the drawbacks of the metal thermoelectric material, can be improved. .

The present inventors have found that uniformly dispersing submicron fine particles in a matrix is an effective method for improving the thermoelectromotive force of the material, and have completed the present invention. is there. That is, in the present invention, a fine dissimilar material is dispersed in the matrix of the metal thermoelectric material, which allows defects to be generated inside the metal material and at the same time strain. Probably
This defect is believed to increase the thermoelectromotive force of the material and further reduce its thermal conductivity. In addition, the thermoelectric material thus obtained can suppress grain growth of the material even at high temperatures, and can maintain the characteristics on the high temperature side.

The raw material of the thermoelectric material of the present invention is a method of using a granular or powdery mixture of a matrix material and a dispersion material, and the raw material of the metal thermoelectric material of the matrix is, for example, Fe, Co, Ni, Pd, Pt. Group VIII or Fe, Co, Ni, Pd, Pt Group VIII and Cu,
A method of using a granular or powdery mixture of Cr, Al, or the like, or a ceramic such as an oxide, a nitride, a carbide, or a boride that can be reduced in hydrogen or vacuum. Specific examples of such ceramics include Ni oxide, Co oxide, Fe oxide, and Cu oxide. Further, the matrix material is Fe,
In addition to Co, Ni, Pd, Pt group VIII, Nd, Sm,
A metal material containing a rare earth metal such as Er as a main component can also be used.

As the matrix material, specifically, Ni
-55 at% Cu, Ni-10 atCr, Ni-10a
Examples thereof include t% Al, Pt-Rh alloy, and the like. The compositions illustrated here are typical ones, so that the constituent elements are not necessarily limited to this composition as long as the constituent elements are the same.

In the present invention, the dispersant dispersed in the matrix may be a metal as long as it is a substance different from the matrix. Due to such different substances, it is possible to provide a difference in the coefficient of thermal expansion between the matrix phase and the dispersion material. Here, the thermal expansion coefficient of the dispersion material is
It is preferably smaller than the matrix, and the difference in thermal expansion coefficient is more preferably 5 × 10 ⁻⁶ / K or more, and the effect of the present invention is particularly exhibited.

Specifically, Al oxide, Si oxide, Mg oxide, Si carbide and the like can be used as the dispersant. The dispersion material is particularly preferably a stable ceramic that does not easily react with the matrix.

The volume ratio of the dispersed phase in the matrix is preferably 0.5% or more and 50% or less, more preferably 1% or more and 10% or less. The thermoelectric material of the present invention can be manufactured as follows using a powder as a raw material of a matrix phase and a dispersant.

As the powder as the raw material of the matrix phase, oxides, nitrides, carbides and borides of metal elements can be used. However, it is required to be easily reduced as compared with an oxide or the like as a dispersant. In other words, the oxide or the like used as the dispersant in the present invention is thermodynamically more stable than the oxide or the like which is the raw material of the matrix phase.

In producing the thermoelectric material, first, the matrix raw material powder and the dispersant are blended in a predetermined ratio and uniformly pulverized and mixed using a ball mill or the like. When the raw material of the matrix material is ceramic powder,
It is desirable to prepare the raw material powder so that the ratio of the reduced material is the composition ratio of the target metal matrix material. Then, using a hydrogen furnace / vacuum furnace, only the raw material of the matrix portion made of the metal thermoelectric material is reduced in a reducing atmosphere.

After mixing, or after mixing and reducing, the thermoelectric material of the present invention is obtained by sintering using hot pressing or the like. The sintering may be performed under normal pressure.
In the texture after sintering, the particle size of the dispersed phase is preferably 1 μm or less, more preferably 0.1 μm or less. When the particle size of the dispersed phase exceeds 1 μm, the particle growth of the matrix may not be suppressed. Further, the particle size of the matrix phase is not particularly limited, but is 10
It is preferably not more than μm, more preferably not more than 1 μm. If the particle size of the matrix phase exceeds 10 μm, the defect density inside the material may be reduced.

In order to obtain a sintered body having such a structure, it is desirable to appropriately select the particle size of the powder of oxide or the like used. By the method as described above, it is possible to manufacture a thermoelectric material having a fine structure with good dispersibility. Further, by selecting the kind of the raw material powder, it is possible to produce an arbitrary p-type or n-type thermoelectric material.

By joining the p-type thermoelectric material thus obtained and the n-type thermoelectric material, a thermoelectric element can be manufactured. An electrode may be interposed between the p-type and n-type junctions, but direct solid phase diffusion bonding is preferable from the viewpoint of reducing the resistance at the interface. Further, when there is no fear that the brazing material and the thermoelectric material form a brittle reaction phase,
An active metal brazing material represented by Ag-Cu brazing material, Ag-Cu-Ti or other metal brazing material may be used.

Further, in order to make the heat on the high temperature side and the heat on the low temperature side uniform, a plate made of ceramics or the like may be sandwiched between the thermoelectric material and the heat source. At this time, the plate and the thermoelectric material are
Methods such as chemical bonding and mechanical contact can be considered. As the ceramic plate, ceramics having high thermal conductivity such as AlN and SiC are preferable, but Al ₂ O ₃
Stable ceramics such as Further, a fin for heat radiation may be provided on the low temperature side to enhance the cooling effect.

FIG. 1 schematically shows an example of a thermoelectric element manufactured using the thermoelectric material as described above. As shown in FIG. 1, the n-type thermoelectric material 1 and the p-type thermoelectric material 2 are PN
It is joined via the joining portion 5. Examples of the n-type thermoelectric material include Cu—Ni—Al ₂ O _{3 and the} like, and examples of the p-type thermoelectric material include Ni—Cr—A.
l ₂ O ₃ can be used. Insulating plates 3 and 4 made of Al ₂ O ₃ and AlN are provided on the high temperature side and the low temperature side, respectively. Further, the radiation fin 7 is arranged on the lower temperature side. In FIG. 1, reference numeral 6 indicates an insulating plate / thermoelectric material joint.

When the thermoelectric element shown in FIG. 1 is manufactured,
Design so that the target output can be obtained when there is a predetermined temperature difference, taking into consideration the electrical resistance determined by the thermoelectromotive force of the material and the material shape (cross-sectional area, length), interface resistance, etc. Is desired.

The thermoelectric element using the thermoelectric material of the present invention can be particularly effectively used for a thermoelectric power generation system utilizing the temperature difference between the waste heat of the gas turbine and the LNG of the fuel. That is, the thermoelectric material as described above can be applied to a site where thermal gradient and thermal shock are repeated and thermal fatigue is large and which cannot be applied conventionally in terms of material strength.

Here, FIG. 2 schematically shows the structure of a thermoelectric generator using the thermoelectric device of the present invention. The thermoelectric generator shown in FIG. 2 includes a thermoelectric element 10, a high temperature heat source inlet 11 to which high temperature exhaust gas is supplied, and a low temperature heat source inlet 12 to which LNG, seawater, etc. are supplied, and the outlet 13 is It is connected to a chimney.

The high temperature heat source may be a refuse incinerator, an automobile engine, etc., in addition to the gas turbine. In the case of a refuse incinerator, it is preferable to cool the low temperature side by using cooling water, and in the case of an automobile, it is preferable to cool the low temperature side by air cooling. At the time of power generation, it is desirable to perform heat calculation and design so that a predetermined temperature difference can be stably obtained.

FIG. 3 shows a schematic diagram of a thermoelectric power generation system utilizing the waste heat of the gas turbine. FIG. 3A shows the case of a non-combined gas turbine.
(B) represents the case of a combined gas turbine. In these figures, 21 is a gas turbine and 22 is L
NG vaporizer, 23 is (LNG vaporizer + thermoelectric power generation), 24
Is a heat exchanger, 25 is a steam turbine, and 26 is exhaust gas.

In the thermoelectric power generation system shown in the figure, exhaust gas (non-combined type: 5
00-600 ° C, combined type (90-200 ° C),
Examples include a casing (200 to 300 ° C.), or a medium heated by the heat exchanger 24 by these heat sources. On the other hand, examples of the low temperature heat source include LNG as a fuel and cooling water such as seawater and water. The thermoelectric materials may be installed by connecting them in series in an existing system, but it is preferable to take out these high and low temperature heat sources in a bypass form for use. Specifically, as shown in the figure, it is inserted in parallel with the LNG vaporizer 21 to perform LN while performing thermoelectric power generation.
It is conceivable to provide a configuration 22 for vaporizing G.

When the exhaust gas from the gas turbine is used, it may be installed directly in the combustion gas or the like, but it is also possible to take out heat by using metal and put it outside.

Since the thermoelectric material of the present invention and the gas turbine plant can be combined as described above, a hydrogen generator for electrolyzing water or seawater using the electric power of the thermoelectric material to generate hydrogen is provided. It can be manufactured.

FIG. 4 schematically shows the configuration of a hydrogen generator using the thermoelectric material of the present invention. As shown in the figure, it is preferable to use natural water such as seawater, and it is preferable to directly take out electric power used for electrolysis from n-type and p-type thermoelectric materials.

The metal-based thermoelectric material has an advantage that a large electric current can be taken out, and by doing so, water can be efficiently decomposed. Therefore, by using the thermoelectric material of the present invention, it has become possible to efficiently generate hydrogen by using the heat that has been discarded. Further, it is also possible to react the hydrogen thus obtained with carbon dioxide contained in the exhaust gas of the gas turbine to synthesize alcohol.

[0038]

BEST MODE FOR CARRYING OUT THE INVENTION The present invention is described in more detail below by showing Examples and Comparative Examples of the present invention, but the present invention is not limited to these Examples. (Example 1) Ni oxide powder having a particle size of 1 μm, Cu oxide powder having a particle size of 1 μm, and aluminum oxide powder having a particle size of 0.02 μm were weighed in predetermined amounts and mixed by a ball mill to prepare a uniformly dispersed mixed powder. .

The obtained mixed powder was transferred to a hydrogen furnace and kept in a mixed gas of hydrogen and Ar at 200 ° C. for 2 hours, and then 3
The temperature was raised to 00 ° C. and held for 2 hours, further raised to 700 ° C. and held for 2 hours, and then furnace cooled to prepare a raw material powder. The composition of the raw material powder is 1: 1: 0.03 by weight.
Met.

Next, the raw material powder was transferred into a vacuum furnace and 1 t
An n-type thermoelectric material was produced by hot pressing at 900 ° C. for 1 hour while applying a pressure of / cm ² . The porosity of the obtained thermoelectric material sintered body was measured and found to be 7%.

The n-type thermoelectric material was provided with a temperature difference between room temperature and 300 ° C., and the thermoelectromotive force was measured and found to be 18 mV. As a result of microscopic observation, it was confirmed that submicron aluminum oxide particles were uniformly dispersed in the submicron metal matrix phase, and the volume ratio of the dispersed phase was 10%. (Comparative Example 1) A small amount of Cu and Ni chip-shaped small pieces were weighed in the same ratio as described above and melted and solidified in an arc melting furnace to produce an n-type thermoelectric material made of an alloy having a uniform composition.
The porosity of the obtained thermoelectric material was 0.001%.

The thermoelectromotive force of this n-type thermoelectric material was measured under the same conditions as above, and was 12 mV. As a result of microscopic observation, it was found that the n-type thermoelectric material was composed of particles having a particle size of 1 μm or more. (Example 2) Ni powder having a particle size of 1 μm, Cr having a particle size of 1 μm
The powder and the aluminum oxide powder having a particle diameter of 0.02 μm were weighed so that the weight ratio was 9: 1: 0.42 and mixed by a ball mill to prepare a uniformly dispersed raw material powder.

The obtained raw material powder was transferred into a vacuum furnace and 1 t
Hot pressing was performed at 900 ° C. for 1 hour while applying a pressure of / cm ² to produce a p-type thermoelectric material. The porosity of this thermoelectric material was measured and found to be 11%.

When the thermoelectromotive force of this p-type thermoelectric material was measured under the same conditions as in Example 1, it was 12 mV. As a result of the structure observation, submicron metal matrix phase was filled with submicron aluminum oxide. It was confirmed that the particles were uniformly dispersed. (Comparative Example 2) A small amount of Ni and Cr chips were weighed and melted and solidified in an arc melting furnace to prepare a p-type thermoelectric material made of an alloy having a uniform composition. The porosity of this thermoelectric material was 0.005%.

The thermoelectromotive force of this p-type thermoelectric material was measured under the same conditions as described above, and was 9 mV. As a result of observing the structure, it was found to be composed of particles having a particle size of 1 μm or more. (Example 3) Using the n-type thermoelectric material obtained in Example 1 and the p-type thermoelectric material obtained in Example 2, a thermoelectric element (module) as shown in FIG. 1 was produced. . The thermoelectric material has a total area c of 0.25 m × 0.25 m = 0.062.
The effective volume of the thermoelectric material required for power generation was 0.25 × 0.25 × 0.01 (cm ³ ), and the thickness was 5 m ² and the thickness was 1 cm.

The output of the thus obtained thermoelectric element under a matched load was measured and found to be 1.5 kW at a temperature difference between 0 ° C. and 500 ° C. The thermoelectric element has an area of 0.25
m ² in combination so that the exhaust gas of the non-combined gas turbine as shown in FIG.
℃) and fuel LNG (-150 ℃) 500
When an attempt was made to generate electricity with a temperature difference of ° C, an output of 6 kW could be obtained. (Comparative Example 3) Example 3 was repeated except that the n-type thermoelectric material obtained in Comparative Example 1 and the p-type thermoelectric material obtained in Comparative Example 2 were used.
When a thermoelectric element having the same size as the above was produced and an attempt was made to generate electricity under the same conditions, the output was 3 kW. (Example 4) Using the n-type thermoelectric material obtained in Example 1 and the p-type thermoelectric material obtained in Example 2, an area of 0.
Thermoelectric element (module) with a thickness of 0625 m ² and a thickness of 1 cm
Was produced. Using this thermoelectric element, the heat of the gas turbine casing (3
(00 ° C) and 25 ° C water were used to generate a temperature difference of 250 ° C to generate electricity.

At this time, since the element (module) was designed to have a structure capable of taking out a large current, an output of about 2 V and 200 A could be taken out. Furthermore, using this element (module), a hydrogen generator as shown in FIG.
When hydrogen was generated, 220 liters of hydrogen could be taken out per hour. (Example 5) Ni oxide powder having a particle diameter of 1 μm, Cu oxide powder having a particle diameter of 1 μm, and aluminum oxide powder having a particle diameter of 0.02 μm were weighed in predetermined amounts and mixed by a ball mill to prepare a uniformly dispersed mixed powder. .

The obtained mixed powder was transferred to a hydrogen furnace and held in a mixed gas of hydrogen and Ar at 200 ° C. for 2 hours, and then 3
The temperature was raised to 00 ° C. and held for 2 hours, further raised to 700 ° C. and held for 2 hours, and then furnace cooled to prepare a raw material powder. The composition of the raw material powder is 1: 1: 0.06 by weight.
Met.

Then, the raw material powder is transferred into a vacuum furnace and 1 t
An n-type thermoelectric material was produced by hot pressing at 700 ° C. for 10 hours while applying a pressure of / cm ² . When the porosity of the obtained thermoelectric material sintered body was measured, it was 20%.

At the room temperature and 300 ° C., the above n-type thermoelectric material is used.
When the thermoelectromotive force was measured with a temperature difference of 17 mV,
Met. As a result of microscopic observation, it was confirmed that the submicron aluminum oxide particles were uniformly dispersed in the submicron metal matrix phase, and the volume ratio of the dispersed phase was 2
It was 0%. (Comparative Example 5) A small amount of Cu and Ni chip-shaped small pieces were weighed in the same ratio as described above and melted and solidified in an arc melting furnace to produce an n-type thermoelectric material made of an alloy having a uniform composition.
The porosity of this thermoelectric material was 0.001%.

When the thermoelectromotive force of this n-type thermoelectric material was measured under the same conditions as above, it was 12 mV. As a result of observing the structure, it was found that the particles were composed of particles having a particle size of 1 μm or more.

[0052]

As described above, according to the present invention,
A thermoelectric power generation system having high power generation efficiency is provided. Such a thermoelectric power generation system exerts a particularly effective effect when applied to a hydrogen generator, and its industrial value is great.

[Brief description of drawings]

FIG. 1 is a schematic diagram schematically showing the configuration of a thermoelectric element using the thermoelectric material of the present invention.

FIG. 2 is a schematic diagram schematically showing the configuration of a thermoelectric power generator using the thermoelectric material of the present invention.

FIG. 3 is a diagram showing a thermoelectric power generation system of the present invention.

FIG. 4 is a schematic view of a hydrogen generator using the thermoelectric material of the present invention.

[Explanation of symbols]

1 ... n-type thermoelectric material 2 ... p-type thermoelectric material 3 ... High temperature side insulation plate 4 ... Low temperature side insulating plate 5 ... PN junction 6 ... Insulation plate / thermoelectric material joint 10 ... Thermoelectric element 11 ... High temperature heat source inlet 12 ... Low temperature heat source inlet 13 ... Outlet 21 ... Gas turbine 22 ... Vaporizer 23 ... Vaporizer + thermoelectric power generation 24 ... Heat exchanger 25 ... Steam turbine 26 ... Exhaust gas

─────────────────────────────────────────────────── ─── Continuation of the front page (51) Int.Cl. ⁷ Identification code FI H02N 11/00 H02N 11/00 A (56) Reference JP-A-9-74229 (JP, A) JP-A-6-302866 ( (58) Fields surveyed (Int.Cl. ⁷ , DB name) H01L 35/22 B22F 9/22 C22C 1/05 C22C 1/10 H01L 35/34 H02N 11/00

Claims (2)

(57) [Claims] 1. A metal matrix and the metal matrix
And a dispersion material dispersed in the cast, the dispersion material,
The metal matrix is composed of different materials.
The waste heat of the gas turbine and the liquid that becomes the fuel
It is characterized by generating electric power by utilizing the temperature difference from chemical natural gas.
Thermoelectric power generation system. 2. The dispersion material contained in the thermoelectric material.
Consists of oxides, nitrides, carbides, and borides
The at least one selected from the group according to claim 1.
Thermoelectric power generation system.