KR102480268B1 - Solid Oxid Fuel Cell and usage systme using thereof - Google Patents

Abstract

The present invention relates to a solid oxide fuel cell and a solid oxide fuel cell utilization system, and the solid oxide fuel cell according to the present invention includes a fuel cell unit including an anode, an air electrode, and an electrolyte unit; and a converter gas supply unit for supplying converter gas generated in the steelmaking process to the anode as it is.
Accordingly, it is possible to produce electricity with high energy efficiency by utilizing the by-product gas generated in the steelmaking process.

Description

Solid oxide fuel cell and solid oxide fuel cell utilization system {Solid Oxid Fuel Cell and usage system using its}

The present invention relates to a solid oxide fuel cell and a solid oxide fuel cell utilization system, and more particularly, to a solid oxide fuel cell and a solid oxide fuel cell utilization system capable of utilizing by-product gas generated in the steelmaking process and exhibiting high energy efficiency. It's about the system.

In each process of the steelmaking process, blast furnace gas (BGF), coke oven gas (COG), converter gas (Linz-Donawitz gas, LDG), and finex off gas (FOG) are used. By-product gas is generated.

Since each of these by-product gases generates millions of tons to tens of millions of tons per year, using by-product gases is preferable in terms of preventing energy waste or environmental pollution.

In the past, by-product gas generated from steelworks was burned and used for combined power generation of gas turbines and steam turbines, or used to produce hydrogen from COG gas containing a large amount of hydrogen.

On the other hand, the solid oxide fuel cell can produce a high firing efficiency of up to 70%, and can use various fuels such as hydrogen as well as hydrocarbon fuels such as natural gas, LPG, propane, and butane, as well as biogas, making it easy to select a fuel. there is free

However, despite the advantage of using various fuels, most of the solid oxide fuel cell technologies currently being developed are based on hydrogen. In addition, natural gas is also used as a fuel for solid oxide fuel cells, but in this case, a complex fuel processing system including a desulfurizer is required because a reformer is used.

Therefore, if the by-product gas generated in the steelmaking process can be used as a fuel for a solid oxide fuel cell without a separate reforming process, it is expected to have an advantageous position in the energy producing industry.

KR 10-2019-0021832 A

Accordingly, an object of the present invention is to solve such conventional problems, and to provide a solid oxide fuel cell and a solid oxide fuel cell utilization system capable of exhibiting high energy efficiency by utilizing by-product gas generated in the steelmaking process. .

The problem to be solved by the present invention is not limited to the above-mentioned problem, and other problems not mentioned will be clearly understood by those skilled in the art from the description below.

The above object, according to the present invention, a fuel cell unit having a fuel electrode, an air electrode and an electrolyte unit; and a converter gas supply unit for supplying converter gas generated in the steelmaking process to the anode as it is.

The converter gas supplier may add water to the converter gas and supply it to the fuel electrode.

The anode may be formed of a NiO-GDC composite material in which NiO and gadolinium doped ceria (GDC) powder are mixed.

The cathode may be formed of a BSCF-GDC composite material in which BSCF (Ba _0.5 Sr _0.5 Co _0.8 Fe _0.2 O _3-δ ) and Gadolinium doped Ceria (GDC) powder are mixed.

The cathode may be formed of a PBSCF (PrBaSrCoFeO) material having a double-perovskite structure.

The support of the electrolyte unit may be made of LSGM ((La, Sr)(Ga, Mg)O ₃ ) material.

According to another embodiment of the present invention, the solid oxide fuel cell; and an exhaust gas utilization unit configured to separate exhaust gas generated from the fuel electrode of the solid oxide fuel cell.

The exhaust gas utilization unit, CO, CO ₂ and N ₂ In the exhaust gas containing CO and CO ₂ Separately separates CO and CO 2 Exhaust gas separation unit, and CO ₂ by adding water to the CO separated in the exhaust gas separation unit And H ₂ It may be provided with an effective gas production unit for producing separately.

The effective gas production unit may use heat generated in the electrolyte unit of the solid oxide fuel cell.

The exhaust gas utilization unit, a second exhaust gas separation unit for separately separating CO and CO ₂ from exhaust gas including CO, CO ₂ and N ₂ , and H ₂ in the CO separated from the second exhaust gas separation unit It may be provided with a chemical substance production unit that produces chemicals composed of C, O and H elements by adding.

The chemical production unit may use H ₂ of by-product gas generated in the steelmaking process.

According to the solid oxide fuel cell of the present invention, the converter gas is used as the fuel of the solid oxide fuel cell, so that energy efficiency can be increased and the environment can be prevented from being polluted by the converter gas.

In addition, a solid oxide fuel cell using converter gas as a fuel can exhibit power density similar to that in the case of using H ₂ as a fuel.

According to the solid oxide fuel cell utilization system of the present invention, energy waste or environmental pollution can be prevented by using converter gas generated in the steelmaking process as fuel for the solid oxide fuel cell, and exhaust gas generated from the solid oxide fuel cell can be prevented. In addition, it can be utilized to maximize the above effect.

1 is a schematic configuration diagram of a solid oxide fuel cell according to the present invention;
2 is a graph of power density test results of a solid oxide fuel cell according to the present invention;
3 is a graph of experimental results regarding the carbon deposition phenomenon of the fuel electrode constituting the solid oxide fuel cell according to the present invention;
4 and 5 are schematic configuration diagrams of a solid oxide fuel cell utilization system according to the present invention.

Hereinafter, specific embodiments of the present invention will be described in detail with reference to the drawings.

1 shows a schematic configuration diagram of a solid oxide fuel cell 10 according to the present invention.

The solid oxide fuel cell 10 according to the present invention includes a fuel cell unit 100 and a converter gas supply unit 200 .

The fuel cell unit 100 includes a fuel electrode 110 , an air electrode 120 and an electrolyte unit 130 . In the anode 110, oxidation of the fuel occurs and electrons are emitted. Electrons move to the cathode 120 through an external wire and generate a DC current. Air containing oxygen is supplied to the cathode 120, and oxygen reacts with electrons to generate oxygen anions. Oxygen anions move to the fuel electrode 110 through the electrolyte unit 130 . The electrolyte unit 130 is made of a solid oxide electrolyte capable of transmitting ions. The fuel cell unit 100 may be formed in the form of an electrolyte support.

The converter gas supply unit 200 supplies the converter gas generated in the steelmaking process to the fuel electrode 110 as it is. The converter gas contained 68% by weight of CO, 12% by weight of CO ₂ , 2% by weight of H ₂ and 18% by weight of N ₂ .

When such a converter gas is supplied to the fuel electrode 110, electrons are generated in the fuel electrode 110 through the following reaction.

H ₂ + CO + 2O ^2- → H ₂ O + CO ₂ + 4e ^-

In the air electrode 120, oxygen anions are generated by the following reaction.

O ₂ + 4e ^- → 2O ^2-

According to the solid oxide fuel cell 10 of the present invention, converter gas is used as a fuel of the solid oxide fuel cell 10, so that energy efficiency can be increased and environmental pollution by the converter gas can be prevented.

In addition, the solid oxide fuel cell 10 using converter gas as fuel can exhibit power density similar to that in the case where H ₂ is used as fuel.

2 shows the power density test results of the solid oxide fuel cell 10 using H ₂ as fuel (FIG. 2(a)) and the power density test of the solid oxide fuel cell 10 using simulated converter gas as fuel. The result (Fig. 2(b)) is shown. In each experiment, an electrolyte-supported single cell using Ni-GDC as the material of the fuel electrode 110 was used.

As shown in FIG. 2, the solid oxide fuel cell 10 using the simulated gas of the converter gas as fuel exhibits the highest power density of 336.6 mW/cm ² at 850 °C and 371.1 mW/cm ² at 850 °C. Since there is no significant difference from a solid oxide fuel cell using H ₂ as a fuel, which exhibits the highest power density of , it can be seen that converter gas can be used as a direct fuel for the solid oxide fuel cell 10 .

Since the power density of the solid oxide fuel cell 10 according to the present invention can be exhibited without separately reforming the converter gas, the energy, time, and manpower required in the process of reforming the converter gas can reduce the power density of the solid oxide fuel cell 10 according to the present invention. The economics of the fuel cell 10 do not deteriorate.

In addition, since converter gas is used as fuel, carbon deposit (Boudouard reaction) phenomenon generated in the anode 110 hardly occurs when carbon compound-based fuel such as CH ₄ is used.

FIG. 3 shows experimental results of carbon deposition on the raw material powder of the anode 110 under a gas atmosphere simulating the CO/CO ₂ fraction of the converter gas. The experiment was conducted through TGA, and in the experiment, Ni-GDC was used as the raw material powder for the fuel electrode 110 .

The theoretical value of the increased weight% (wt%) when Ni-GDC is oxidized with air is 15.07wt%, and the error range is less than 1wt%. As shown in FIG. 3, the increased wt% when Ni-GDC is oxidized with the simulated gas of the converter gas is 14.80 wt% at 750 ° C, 14.94 wt% at 800 ° C, 14.93 wt% at 850 ° C, and 900 ° C It was found to be 14.89wt% in That is, when converter gas is used as fuel, it can be expected that carbon deposition by fuel will hardly occur in the anode 110 through a difference between the theoretical value and the error range occurring at 750° C. or higher.

Accordingly, unlike the case where a large amount of water must be used to maintain a high steam/carbon fraction to prevent carbon deposition in the case of using carbon compound-based fuel, in the present invention there is no need to use water. Deterioration of durability of the solid oxide fuel cell 10 due to moisture can be prevented.

The converter gas supplier 200 may add water to the converter gas and supply it to the fuel electrode 110 .

Water added to the converter gas generates hydrogen as shown in the following reaction equation by a water-gas shift reaction, and it is possible to use hydrogen as a fuel for the solid oxide fuel cell 10 in addition to the converter gas. In addition, since the hydrogen fraction in the converter gas is increased, the reaction in the fuel electrode 110 may proceed more actively.

CO + H ₂ O → CO ₂ + H ₂

Even if water is added to the converter gas, since it is converted into carbon dioxide and hydrogen by the above-described water gas shift reaction, there is no concern that the durability of the solid oxide fuel cell 10 is deteriorated by water.

The fuel electrode 110 may be formed of a NiO-GDC composite material in which NiO and gadolinium doped ceria (GDC) powder are mixed. The fuel electrode 110 made of the NiO-GDC composite material can sustain high output of the solid oxide fuel cell 10 because carbon deposition hardly occurs. The anode 110 may be formed by making NiO-GDC powder into a paste and screen printing it on one side of the electrolyte unit 130 .

The cathode 120 may be formed of a BSCF-GDC composite material in which BSCF (Ba _0.5 Sr _0.5 Co _0.8 Fe _0.2 O _3-δ ) and Gadolinium doped Ceria (GDC) powder are mixed. Since the BSCF-GDC composite material has high ion conductivity and electron conductivity, superior electrical properties are imparted to the cathode 120. The air electrode 120 may be formed by making a paste of the BSCF-GDC powder and screen-printing the other side of the electrolyte unit 130 .

The cathode 120 may be made of a PBSCF (PrBaSrCoFeO) material having a double-perovskite structure. The PBSCF (PrBaSrCoFeO) material has excellent catalytic activity and can increase the maximum power density of the solid oxide fuel cell 10 .

The support of the electrolyte unit 130 may be made of LSGM ((La, Sr)(Ga, Mg)O ₃ ) material. Since LSGM has low resistance, it has excellent ionic conductivity and can improve the output of the solid oxide fuel cell 10 .

Hereinafter, a solid oxide fuel cell utilization system 1 according to the present invention will be described. While the solid oxide fuel cell utilization system 1 according to the present invention is described, detailed descriptions of parts mentioned in the description of the solid oxide fuel cell 10 according to the present invention may be omitted.

4 and 5 show a schematic configuration diagram of a solid oxide fuel cell utilization system 1 according to the present invention.

The solid oxide fuel cell utilization system 1 according to the present invention includes the above-described solid oxide fuel cell 10 and an exhaust gas utilization unit 20 .

The solid oxide fuel cell 10 includes a fuel cell unit 100 and a converter gas supply unit 200, and the converter gas supply unit 200 supplies the converter gas generated in the steelmaking process as it is to the fuel electrode 110 of the fuel cell unit 100. ) to supply

The exhaust gas utilization unit 20 separates the exhaust gas generated from the fuel electrode 110 of the solid oxide fuel cell 10 by component. The exhaust gas generated from the anode 110 of the solid oxide fuel cell 10 may include CO, CO ₂ and N ₂ , and among them, CO and CO ₂ may be utilized.

According to the solid oxide fuel cell utilization system 1 of the present invention, waste of energy or environmental pollution can be prevented by using converter gas generated in the steelmaking process as fuel for the solid oxide fuel cell 10, and solid oxide Exhaust gas generated from the fuel cell 10 can also be utilized, so that the above effect can be maximized.

More specifically, the exhaust gas utilization unit 20 may include an exhaust gas separation unit 21 and an effective gas production unit 22 as shown in FIG. 4 .

The exhaust gas separator 21 separates CO and CO ₂ from exhaust gas containing CO, CO ₂ and N ₂ . The exhaust gas separator 21 may separate CO and CO ₂ from the exhaust gas through, for example, a gas separation membrane (GSM) 21a.

In the effective gas production unit 22, CO ₂ and H ₂ are separately produced by adding water to the separated CO. The effective gas production unit 22 may include, for example, a water gas shift membrane reactor (WGS-MR) 22a to produce hydrogen through a water gas shift reaction of CO. CO ₂ and H ₂ produced through the water gas shift reaction may be separated separately through a hydrogen separation membrane (H ₂ -separation membrane) 22b.

CO ₂ produced in the effective gas production unit 22 may be made highly pure by condensing water vapor, and then compressed and stored together with the CO ₂ separated in the exhaust gas separation unit 21 .

The effective gas production unit 22 may use heat generated in the electrolyte unit 130 of the solid oxide fuel cell 10 . Heat can make the water gas shift reaction proceed more actively in WGS-MR.

Accordingly, it is possible to further increase the energy efficiency of the solid oxide fuel cell utilization system 1 .

As shown in FIG. 5 , the exhaust gas utilization unit 20 may include a second exhaust gas separation unit 23 and a chemical production unit 24 .

The second exhaust gas separator 23 separates CO and CO ₂ from exhaust gas containing CO, CO ₂ and N ₂ . The second exhaust gas separator 23 may separate CO and CO ₂ from the exhaust gas through, for example, the GSM 23a.

In the chemical production unit 24, H ₂ is added to the CO separated in the second exhaust gas separation unit 23 to produce chemicals composed of C, O, and H elements. Chemicals produced by the chemical production unit 24 may include, for example, high value-added chemicals such as methanol, ethylene, propylene, and olefin.

The CO ₂ separated by the second exhaust gas separator 23 may be compressed and stored.

The chemical production unit 24 may produce chemicals using H ₂ of by-product gas generated in the steelmaking process.

Accordingly, since there is no need to separately supply H ₂ , it is possible to economically produce chemicals.

The scope of the present invention is not limited to the above-described embodiments, but may be implemented in various forms of embodiments within the scope of the appended claims. Anyone with ordinary knowledge in the art to which the invention pertains without departing from the subject matter of the invention claimed in the claims is considered to be within the scope of the claims of the present invention to various extents that can be modified.

1: Solid oxide fuel cell utilization system
10: solid oxide fuel cell 20: exhaust gas utilization unit
21: exhaust gas separation unit 22: effective gas production unit
23: second exhaust gas separation unit 24: chemical production unit
100: fuel cell unit 110: fuel electrode
120: air electrode 130: electrolyte unit
200: converter gas supply unit

Claims (11)

solid oxide fuel cells; and
An exhaust gas utilization unit separating exhaust gas generated from the fuel electrode of the solid oxide fuel cell;
The solid oxide fuel cell,
a fuel cell unit including a fuel electrode, an air electrode, and an electrolyte unit; and
To the fuel electrode, the converter gas generated in the steelmaking process and containing CO, CO ₂ , H ₂ and N ₂ is supplied as it is, but the fraction of CO ₂ and H ₂ is reduced by adding water to the converter gas. A converter gas supply unit that increases and supplies; includes,
The exhaust gas utilization unit,
A system utilizing a solid oxide fuel cell, characterized in that separate CO and CO ₂ are separated from exhaust gas containing CO, CO ₂ and N ₂ .
delete According to claim 1,
The fuel electrode is a solid oxide fuel cell utilization system, characterized in that made of a NiO-GDC composite material in which NiO and GDC (Gadolinium doped Ceria) powder are mixed.
According to claim 1,
The cathode is made of a BSCF-GDC composite material in which BSCF (Ba _0.5 Sr _0.5 Co _0.8 Fe _0.2 O _3-δ ) and GDC (Gadolinium doped Ceria) powder are mixed. System for utilizing a solid oxide fuel cell.
According to claim 1,
The cathode is a solid oxide fuel cell utilization system, characterized in that made of PBSCF (PrBaSrCoFeO) material having a double-perovskite structure.
According to claim 1,
The solid oxide fuel cell utilization system, characterized in that the support of the electrolyte part is made of LSGM ((La, Sr) (Ga, Mg) O ₃ ) material.
delete According to claim 1,
The exhaust gas utilization unit,
An exhaust gas separation unit that separately separates CO and CO ₂ from exhaust gases including CO, CO ₂ and N ₂ , and
A solid oxide fuel cell utilization system comprising an effective gas production unit for separately producing CO ₂ and H ₂ by adding water to the CO separated in the exhaust gas separation unit.
According to claim 8,
The solid oxide fuel cell utilization system, characterized in that the effective gas production unit uses the heat generated in the electrolyte unit of the solid oxide fuel cell.
According to claim 1,
The exhaust gas utilization unit,
A second exhaust gas separator for separately separating CO and CO ₂ from exhaust gas including CO, CO ₂ and N ₂ , and
The solid oxide fuel cell utilization system, characterized in that it comprises a chemical production unit for producing a chemical material consisting of C, O and H elements by adding H ₂ to the CO separated in the second exhaust gas separation unit.
According to claim 10,
The chemical production unit is a solid oxide fuel cell utilization system, characterized in that using H ₂ of the by-product gas generated in the steelmaking process.

Images