KR100966098B1 - Scandia doped cubic yttria stabilized zirconia and solid oxide fuel cell using them - Google Patents

Abstract

The present invention is a conventional yttria stabilized zirconia (YSZ) so that the solid oxide fuel cell using yttria stabilized zirconia (YSZ) as a solid electrolyte can be stably used in the mid- and low temperature region below 800 ℃. The present invention relates to a cubic yttria-stabilized zirconia electrolyte in which a Scandia substituted solid solution is improved by about two times the ion conduction property of an electrolyte, and a solid oxide fuel cell using the same. The zirconia electrolyte described above has high conductivity characteristics and excellent phase stability while maintaining excellent mechanical strength, while maintaining the same power density (W / cm ² ) of the conventional solid oxide fuel cell while lowering the battery operating temperature than the conventional fuel. The effect of ensuring long-term stability of the battery can be obtained.

 Stabilized Zirconia Electrolyte, Solid Oxide Fuel Cell, Oxygen Sensor, Oxygen Separator

Description

Scandia doped cubic yttria stabilized zirconia and solid oxide fuel cell using them

The present invention relates to a solid electrolyte which is a core component of a solid oxide fuel cell (hereinafter referred to as SOFC), and a conventional yttria (Y ₂ O ₃ ) stabilized zirconia (ZrO ₂ ) electrolyte (hereinafter referred to as YSZ). A cubic yttria stabilized zirconia electrolyte ((Y ₂ O ₃ ) _x (Sc ₂ O ₃ ) substituted with Scandia (Sc ₂ O ₃ ) substituted solid solution which maintains excellent phase stability and mechanical properties while significantly improving oxygen ion conduction characteristics. ) _y (ZrO ₂ ) _1-xy , 0.10 ≦ x + y ≦ 0.11, hereinafter abbreviated as YScSZ) and a solid oxide fuel cell using the same.

SOFC is composed of both metal oxide and electrolyte material. It is an energy conversion device that directly converts chemical energy of fuel gas into electrical energy through electrochemical reaction at high temperature of 550 ~ 1000 ℃. This SOFC has the highest power conversion efficiency among several fuel cell types, and has the advantage of combining power generation with a gas turbine using high quality waste heat, and is being regarded as a representative medium-large temperature high temperature fuel cell. In addition, SOFC is attracting attention as an environmentally friendly next-generation power supply device with little pollution such as NO _x , SO _x, or CO _2, and does not use precious metal elements such as expensive platinum as electrodes. Among the components of SOFC, electrolyte is the most important key material that determines the output and service temperature of SOFC. Zirconia ((Y ₂ O ₃ ) _0.08 (ZrO ₂ ) _{0.92 with} 8 mol% yttria stabilizer, 8YSZ) shows high ionic conductivity of about 0.1S / cm at 1000 ℃, shows excellent chemical stability and high mechanical strength, and is the most commonly used electrolyte in SOFC as well as oxygen sensor materials for exhaust gas control of automobiles. It is a substance.

Many studies have been made for the commercialization of SOFC, but it is used for a long time due to material degradation such as material crack, interfacial reaction between components and sintering of porous electrode due to high temperature operation above 800 ℃ There are many difficulties. Therefore, recent research has focused on securing economics that can lower the operating temperature of SOFC below 800 ° C to prevent material deterioration, and ultimately secure stability for long-term operation, and use low-cost metal connecting materials to achieve commercialization. Doing. However, the 8YSZ electrolyte shows high ionic conductivity of about 0.1 S / cm at 1000 ° C., but when the temperature is lowered to 800 ° C., the ionic conductivity rapidly decreases to about 0.03 S / cm, resulting in a significantly lower battery output.

In order to solve the deterioration of the electrolyte, research on the development of an alternative electrolyte that can be used at low temperatures has been actively conducted in Japan, Europe, and the United States. As a result of many studies, promising materials as alternative electrolytes are perovskite compounds based on ceria (CeO ₂ ), lanthanum and gallium added with gadolium (Gd) or samarium (Sm) (e.g. La _1-x Sr _x Ga _1-y Mg _y O ₃ ; hereafter abbreviated as LSGM) and 8-12 mol% Scandia as a stabilizer (zirconia-based electrolyte ((Sc ₂ O ₃ ) _x (ZrO ₂ ) _1-x , hereinafter referred to as ScSZ)) Etc. All of these materials have significantly higher oxygen ion conductivity than the conventional 8YSZ electrolyte, but the ceria-based electrolyte is reduced in the reducing atmosphere of the anode, which results in a higher electron conductivity than the ion conductivity, and the LSGM electrolyte has a nickel (Ni) metal of the anode. Easily react with and form a nonconductive secondary reaction product. 11 mol% Scandia-stabilized zirconia (Sc ₂ O ₃ ) _0.11 (ZrO ₂ ) _0.89 , 11ScSZ is the ideal electrolyte composition without deterioration of conductivity value even after long time operation, but it is cubic crystal in single crystal crystal structure around 630 ℃. Phase transformation occurs due to the structure. This phase transformation is accompanied by a sharp lattice distortion and a change in the volume of the electrolyte and consequently a major defect in the mechanical stability of the SOFC.

In order to prevent such phase transformation, Japan tried to suppress phase transformation by substituting 1 mol% of ceria (CeO ₂ ) or bismuth oxide (Bi ₂ O ₃ ) and various other substances in part of 11 mol% of Scandia components. There is a drawback of reducing at the anode, and bismuth oxide shows a drawback of volatilization at high temperatures. In addition, Scandia is a very expensive material, and these materials bring about 5 times higher material costs than the existing 8YSZ. Therefore, alternative electrolytes are not yet actively applied to SOFCs. I use it.

The present invention, while maintaining a high output density at a temperature of 800 ℃ or less while ensuring the long-term stability and durability to induce the commercialization of SOFC, while maintaining the excellent chemical stability and high mechanical strength of the advantages of the conventional 8YSZ electrolyte An object of the present invention is to provide a yttria zirconia electrolyte stabilized with a cubic crystal structure in which a part of yttria, which is a stabilizer, having high ionic conductivity is substituted with Scandia for solid solution, and a solid oxide fuel cell using the same.

The composition of the Scandia substituted cubic yttria stabilized zirconia electrolyte prepared through the present invention for the above purpose is represented by the formula (Y ₂ O ₃ ) _x (Sc ₂ O ₃ ) _y (ZrO ₂ ) _1-xy ( YScSZ hereinafter), and the high capacity (x + y) of the total stabilizer is in the range of 0.10 ≦ x + y ≦ 0.11. Both YSZ and ScSZ electrolytes have a high temperature conductivity tend to decrease over time when the stabilizer is employed at less than 10 mole percent, so that the total stabilizer is preferably at least 10 mole percent (x + y = 0.1). If 11 mole% (x + y = 0.11) is exceeded, the conductivity of the electrolyte cannot be improved even if the solid solution is increased, but rather, the oxygen vacancies are combined to reduce the oxygen ion path, thereby lowering the conductivity value and increasing the amount of relatively expensive stabilizer. There is a disadvantage of increasing the cost of manufacturing the electrolyte. In addition, the high dose of Scandia should be limited to less than 5 mol% (y <0.05) and less than the high dose of yttria, the main stabilizer (x> y).

In general, commercially available zirconia solid solution powders are prepared by a liquid phase method such as coprecipitation, hydrolysis, hydrothermal synthesis, and the like, and the electrolyte powder of the present invention is also preferably manufactured using such a liquid phase method. In the liquid phase method, an initial raw material may be a water-soluble metal compound such as nitrate, chloride and acetate among Y, Sc and Zr compounds. In addition, the synthesized electrolyte powder should be synthesized to obtain a high sintered density of 95% or more at 1400 ° C., which is advantageous for the actual SOFC unit cell manufacturing process.

The YScSZ electrolyte obtained through the present invention is capable of operating at a temperature lower than the conventional SOFC operating temperature by exhibiting a conductivity characteristic that is about 2 times higher than that of the conventional 8YSZ electrolyte. The cathode and anode materials may use materials mainly used in existing SOFCs.

1 illustrates a unit cell configuration of an YScSZ electrolyte and a solid oxide fuel cell having an air electrode and a fuel electrode attached to both surfaces thereof according to the present invention. Commonly used cathode materials include lanthanum (La) manganese (Mn) oxide with strontium (Sr) having a perovskite structure (ABO _3, A = rare earth and alkaline earth metals, B = transition metals, O = oxygen). (La _1-x Sr _x MnO ₃ hereinafter abbreviated as LSM) and LSM + YSZ composite material. However, this composition is a high temperature (800 ~ 1000 ℃) SOFC cathode material, and the perovskite-based oxygen ion and electron mixed conductive material (hereinafter referred to as MIEC) are used to increase the output characteristics of SOFC for medium and low temperature in which YScSZ electrolyte is introduced. desirable. The composition of these mixed conductors is as follows. A site metal element is composed of one or two elements of rare earth elements such as lanthanum (La), samarium (Sm), praseodymium (Pr), or alkaline earth elements such as barium (Ba) and strontium (Sr). . B-site metal elements are transition metals such as manganese (Mn), cobalt (Co), iron (Fe), copper (Cu) and nickel (Ni) elements, and consist of one or two elements. In order to further improve the cathode characteristics by increasing the area of the three-phase interface, which is an electrochemical reaction point, a composite cathode material composed of MIEC + YScSZ or MIEC + (zirconia-based or ceria-based electrolyte) is advantageous.

In the case of the anode, a conventional Ni + YSZ composite electrode can be used or a Ni + YScSZ composite electrode or a Ni + ScSZ composite electrode can be used to increase the electrochemical characteristics of the anode. The volume fraction of the anode support is so high that it is not economically advantageous. However, in the case of the anode support type SOFC, the support uses Ni + YSZ and the Ni + YScSZ composite electrode or the Ni + ScSZ composite electrode is used as a functional layer for the electrochemical reaction, thereby reducing the manufacturing cost and increasing the electrochemical characteristics. It is preferable to be able.

The above-described SOFC unit cells can be manufactured in flat, cylindrical and flat SOFC structures, and the electrode support can be pressed at room temperature, tape-casting, extrusion, or thermal spraying. ) Can be prepared. In the case of YScSZ electrolyte preparation, the electrolyte powder is prepared as a paste and a slurry by mixing with an organic compound, and used for screen printing, vacuum slurry coating, tape casting or dipping. coating) and can also be coated by thermal spraying. In the case of the opposite electrode, cold spraying, screen printing, immersion and thermal spraying are possible.

SOFC based on the existing 8YSZ electrolyte could not lower the operating temperature below 800 ℃ due to the low ion conduction characteristics of the 8YSZ electrolyte. Therefore, an expensive heat-resistant alloy should be used as a metal linking agent, and as a side effect, chromium (Cr) in the heat-resistant alloy has a disadvantage of deteriorating the electrochemical characteristics of the cathode, which makes it difficult to commercialize. The cubic YScSZ high performance electrolyte prepared according to the present invention maintains the mechanical and chemical stability of the existing 8YSZ electrolyte while simultaneously solving the low ion conductivity characteristics of the 8YSZ electrolyte and the phase transformation and the high price of the ScSZ electrolyte, thereby reducing the SOFC operating temperature by 800. By lowering it below ℃, it is possible to reliably use inexpensive commercial stainless-based metal linkages such as STS 430 alloy, and the low operating temperature has the effect of ensuring long-term stability and durability of SOFC.

The following presents examples for preparing YScSZ electrolyte in order to more easily understand the present invention. However, the following examples are provided only to assist in understanding the present invention is not limited to the following examples.

     Example (Preparation of YScSZ Electrolyte)

The present embodiment is an example of synthesizing the YScSZ electrolyte powder using a hydrothermal synthesis method and preparing a sintered body to check the physical properties of the YScSZ electrolyte. The compositional formula of YScSZ prepared through this example can be expressed as (Y ₂ O ₃ ) _0.051 (Sc ₂ O ₃ ) _0.049 (ZrO ₂ ) _0.9 and yttrium nitrate [Y (NO ₃ ) _{3 ·} H ₂ O as an initial raw material. ], Using a scandium nitrate [Sc (NO ₃ ) ₃ H ₂ O], and zirconium oxychloride [ZrOCl ₂ H ₂ O], the molar ratio of Y ₂ O ₃ : Sc ₂ O ₃ : ZrO ₂ is 5.1: The initial raw materials were weighed to 4.9: 90 and dissolved in ultrapure water to prepare a mixed metal salt aqueous solution such that the concentration of the total metal salt was 0.25 mol (M). The mixed metal salt solution was kept at 80 and stirred continuously. Ammonia water of 5 normal (N) concentration was added dropwise to the mixed aqueous metal salt solution while stirring until the pH reached 9 at a rate of 200 mL / h. The stirring was stopped and the resulting precipitated metal hydride (metal hydroxide) was kept for 12 hours to precipitate, then the upper aqueous solution was decanted and washed with ultrapure water again. After this washing was repeated five times, ammonia ions and chlorine ion impurities (NH ⁴⁺ , Cl ⁻ ) in the hydrate were removed by ultrapure water using a vacuum filter. The presence of chlorine ions was confirmed by reacting a 0.1 molar silver nitrate (AgNO ₃ ) aqueous solution with the filtered solution.

The washed hydrate gel was again dispersed in distilled water and subjected to hydrothermal crystallization at 175 ° C. for 12 hours while stirring in a hydrothermal synthesizer equipped with a metal reactor. There was no separate pressurization and only natural pressure generated by hot hydrothermal reaction was used. The hydrothermal crystallized electrolyte nano powder was dried at 110 ° C. for 12 hours, and the dried nano powder was pulverized first. In order to grow the particles of the pulverized nanopowder was calcined at 750 ℃ for 2 hours and the temperature increase rate was set to 5 per minute. The calcined powder was ball milled for 24 hours using an ethanol solvent and a 5 mm diameter zirconia grinding ball.

In order to analyze the particle shape of the electrolyte powder obtained through the above-described process, it was observed using a transmission electron microscope (TEM), and the results are shown in FIGS. 2 and 3. FIG. 2 is a transmission electron microscope (TEM) image of ultrafine nanopowders of YScSZ electrolyte prepared by hydrothermal synthesis, and it can be seen that the nanoparticles have a crystal size of about 5 nanometers (nm) and are made of spherical particles. 3 is a transmission electron micrograph of the powder obtained by calcining the hydrothermally synthesized powder of FIG. 2 at 700 ° C. for 2 hours. The crystal size of the powder was grown to about 10 nanometers, and formed agglomerates having a size of 0.1 to 0.9 micron through heat treatment. It can be confirmed.

In order to confirm the crystal structure of the hydrothermally synthesized electrolyte powder, the results of analysis using an X-ray diffraction analyzer (XRD) are shown in FIG. 4. XRD analysis showed that the first hydrate exhibited an amorphous structure and exhibited low and high peak widths seen in typical nanopowders through hydrothermal crystallization. In addition, it was confirmed that crystallinity was improved through grain growth using calcination treatment. It is known that the greatest advantage of the hydrothermal synthesis method is that it is possible to prepare nano powder having excellent spherical dispersibility, and even in the case of the electrolyte powder synthesized through TEM analysis, it was confirmed that the spherical nano particles having excellent dispersibility were well formed.

The final calcined and pulverized electrolyte powder was formed in a disc shape by uniaxial pressure molding, and then sintered at 1400 ° C. for 2 hours to prepare a sintered body. The results of analyzing the sintered compact using XRD are shown in FIG. 5, and it was confirmed that the crystal structure of the sintered compact was a perovskite cubic crystal structure in which crystals were well developed. The microstructures of the surfaces and fracture surfaces of these sintered bodies were analyzed using a scanning electron microscope (SEM), and these are shown in FIGS. 6 and 7, respectively. The electrolyte sintered body prepared by using nano powder showed very dense microstructure and clear cubic crystal structure at room temperature.

In addition, the ion conductivity of the electrolyte sintered body was measured in the temperature range of 700 ~ 900 ℃ using a DC 4-terminal method and the results are shown in FIG. The conductivity of the YScSZ electrolyte according to the present invention is 0.034 S / cm, 0.051 S / cm, 0.08 S / cm, 0.11 S / cm and 0.16 S / cm at 700 ° C, 750 ° C, 800 ° C, 850 ° C and 900 ° C, respectively. Indicated.

Compared with the 8YSZ electrolyte, the YScSZ electrolyte showed about twice the higher ionic conductivity than the conventional 8YSZ electrolyte at 0.08 S / m at 800 ° C. Also, at 700 ° C, 0.034 S / cm showed similar values to the ion conductivity of the conventional 8YSZ electrolyte at 800 ° C. Based on these ionic conductivity values, SOFCs using YScSZ electrolytes can reduce the operating temperature to about 700 ° C while ensuring long-term stability.

1 is a block diagram of a solid oxide fuel cell comprising an YScSZ electrolyte and an electrode having an electrode and a fuel electrode formed on both surfaces thereof according to the present invention.

2 is a transmission electron microscope (TEM) photograph of ultrafine nanopowders of YScSZ electrolyte prepared by hydrothermal synthesis method

FIG. 3 is a transmission electron microscope photograph of the powder calcined at 750 ° C. for 2 hours.

4 is an X-ray diffraction diagram of the ultra fine powder of FIG.

FIG. 5 is an X-ray diffraction diagram of a specimen sintered at 1400 ° C. for 2 hours after uniaxial pressure molding of the electrolyte powder of FIG. 2.

6 is a scanning electron micrograph of the surface of the specimen sintered for 2 hours at 1400 ℃ after uniaxial pressure molding the electrolyte powder of FIG.

7 is a scanning electron micrograph of the specimen fracture surface sintered for 2 hours at 1400 ℃ after uniaxial pressure molding the electrolyte powder of FIG.

8 is an electrical conductivity graph of a specimen sintered at 1400 ° C. for 2 hours after uniaxial pressure molding of the electrolyte powder of FIG.

FIG. 9 is an electrical conductivity graph of the electrical conductivity of FIG. 8 expressed in an Arrhenius function as a function of log S / cm and 1 / T.

Claims (2)

(Y ₂ O ₃ ) _x (Sc ₂ O ₃ ) _y (ZrO ₂ ) _1-xy and the high capacity of the total stabilizer (Y ₂ O ₃ + Sc ₂ O ₃ ) is 0.07≤x + y≤0.12 and, the main stabilizing agent is yttria (Y ₂ O ₃₎ of high capacity is a capacity of scandia (Sc ₂ O ₃₎ than the high-capacity large (x> y) of, scandia (Sc ₂ O ₃₎ is greater than or equal to 1 mol% to 5 mol A Scandia substituted solid solution cubic yttria stabilized zirconia electrolyte, characterized by consisting of less than% (0.01 ≦ y <0.05). The cathode material which can be used as a solid oxide fuel cell in which the Scandia-substituted cubic yttria stabilized zirconia substituted with solid solution is used as the electrolyte and the cathode and the anode are attached to both sides of the electrolyte is La _1-x Sr _x MO ₃ (x = 0.1 to 0.3, M = Mn, Fe, Co, Cu, Ni element or a mixture of one or two) using the material of the perovskite structure selected from the material of the perovskite structure and 8YSZ, YScSZ and ScSZ A solid oxide fuel cell using a composite electrode in which one of the zirconia electrolytes is mixed, and a composite electrode in which the Ni electrode and the zirconia electrolytes of 8YSZ, YScSZ and ScSZ are mixed in the case of the anode material.

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