TWI708747B - A method of preparation and application for glass ceramic sealing thin strips - Google Patents

Abstract

A method of preparation and application for a glass ceramic sealing thin strip with high sealing performance, differentiating from using conventional glass ceramic package paste applied to the junction of the battery stack assembly and the connecting plate. The present invention utilizes tape casting to produce a glass ceramic sealing thin strip, stacking single layer or multi-layer in accordance with the required thickness of the glass ceramic sealing thin strip, and cutting the glass ceramic sealing thin strips in accordance with the geometry of battery stacks with equal thickness of the glass ceramic sealing thin strip for battery stack assembly, overcoming the setbacks of the conventional dispensing glass ceramic package paste method that makes the thickness difficult to control, thus, to effectively improve sealing performance of the battery stack assembly, improve the power generation efficiency, and achieve commercial application with mass production.

Description

Manufacturing and application method of glass ceramic sealing ribbon

The present invention relates to the manufacturing and sealing procedures of sealing glass-ceramic ribbons, in particular to a scraper forming technique to produce glass-ceramic ribbons with specific formulations.

In the packaging technology of solid oxide fuel cell (Solid Oxide Fuel Cell, SOFC) stacks, glass ceramic powder with good sealing effect is generally used to mix different types of grinding and mixing in proportion to prepare the sealing glass glue. Alcohols, binders and plasticizers are mixed and stirred to defoam to obtain glass glue; in application, the glass glue is applied to the joints between the components of the battery stack and the cells, and the sealing effect is produced by high temperature pressing. This method is not suitable for continuous and large-scale battery stack packaging operations. At the same time, the thickness of the packaging glue is prone to uneven thickness due to the time difference of the coating sequence, resulting in defects and leakage during high-temperature sealing. In the present invention, the use of thin tape to seal the battery stack has the advantages of mass production and controllable sealing glue size, and empirical data is provided in the examples.

The conventional battery stack encapsulation is to dispense the prepared sealant on the components. It is suitable for continuous and large-scale battery stack packaging operations. At the same time, the thickness of the packaging glue is prone to uneven thickness due to the time difference of the coating sequence, resulting in defects and leakage during high-temperature sealing. In the present invention, the use of thin tape to seal the battery stack has the advantages of mass production and controllable sealing glue size, and empirical data is provided in the examples.

The main purpose of the present invention is to propose a sealing glass-ceramic ribbon production and sealing procedures to improve the solid oxide fuel cell membrane electrode assembly (MEA) or unit cell (referred to as SOFC-MEA or Unit Cell) in the stack and phase The sealing characteristics of the joint of adjacent components and improve the electrical performance. The present invention uses thin strips to seal the battery stack with mass production and controllable sealing glue size, so it can effectively improve the output power density of the battery due to the excellent sealing state when the same battery element is assembled and tested in the single cell stack. Stable long-term power output. At the same time, the thin strip forming and manufacturing can be carried out on a small-scale mass production scale, and the thin strips can be stacked through different layers to meet the packaging conditions required to meet the target thickness of different solar cells.

The process of the present invention is to develop the sealing glass ribbon using a doctor blade forming formula, and the slurry is formed into a soft glass ceramic substrate green embryo by the doctor blade forming process; and stacking and battery stack assembly applications are performed according to different target thicknesses.

S1: Preparation of green glass ceramic sealing strip substrate by scraper forming method

S2: The thin sealing tape is stacked and pressed according to the specifications of the cell used to achieve the target thickness

S3: Cooperate with battery stack assembly for geometric shape cutting, packaging and high temperature pressing procedures

S4: Laminate the sealed glass ceramic thin tape between the cell and the cell stack for cell stack assembly operations

S5: Carry out sealing glass ceramic thin tape package parameter test

S6: Conduct an anode-supported solid oxide fuel cell electrical performance test and comparison results

Figure 1 is a schematic diagram of a brief implementation of the procedure of the present invention.

Figure 2. The cutting shape of the glass ceramic sealing ribbon according to the battery assembly design.

Figure 3. Preliminary adjustment of the packaging conditions, the electrical performance test results of sample A.

Figure 4. Optimized packaging conditions, electrical performance test results of sample B.

A preferred embodiment of the glass ceramic sealing ribbon preparation and battery stack assembly application method of the present invention and the manufacturing method thereof. The glass ceramic material used in this preferred embodiment is commercial glass ceramic powder, but not Limit; any glass ceramic material with high temperature sealing characteristics is in line with the spirit of the present invention. The solid oxide fuel cell battery product used can be a commercial solid oxide fuel cell. The battery solid oxide fuel cell used in this preferred embodiment is a self-made anode supported solid oxide fuel cell. But not limited to this. The specific steps are as follows:

Step 1: The glass-ceramic sealing ribbon of the present invention and its manufacturing method for a brief schematic diagram of the implementation, please refer to Figure 1. First select a glass-ceramic material with sealing properties, adjust the ceramic powder into a slurry and prepare it by a doctor blade forming process Substrate green embryo; the composition of the slurry is mainly composed of glass-ceramic materials with sealing characteristics, combined with organic solvents, dispersants, plasticizers, pore-forming agents and bonding agents, through specific and fine composition preparation procedures to produce special formula slurry for application In the doctor blade molding process, the sealing thin ribbon ceramic green embryo is produced. The example values of the weight composition of the slurry components are: sealing glass ceramic material (glass cermics) 68wt%, methyl ethyl ketone (MEK) (17wt%), ethanol (Ethyl Alcohol, EtOH) 7wt%, Triethylamine (TEA) 1.5wt%, Di-n-butyl Phtalate (DBP) 1.0wt%, Polyethylene Glycol (Polyethylene) glycol, PEG) 1.0wt%, polyvinyl butyral film (Polyvinyl Butyral Film, PVB) 4.5wt%, in which the thickness of the monolithic sealed thin strip green embryo is between 80 and 200 μm.

Step 2: The green sealing glass ceramic ribbon prepared by the doctor blade is combined and laminated to produce a sealing ribbon with a total thickness of 300~800μm through the heat lamination and water pressure equalization process. The number of stacked sheets depends on The size of the single green embryo depends on the target size. The size of the overall sealing ribbon is matched with commercial solid oxide fuel cell chips to be made into 10×10~15×15cm ² . Before the battery stack is sealed and assembled, according to the geometric shape required for the battery stack package, the single-piece battery stack assembly thin strip kit is cut by a mold and attached to the battery chip and the battery stack assembly for the stack assembly process. Then, at 800~900℃, perform high temperature softening sealing and pressing for 4 to 24 hours to obtain a fully packaged single cell stack assembly kit. The increase in temperature and the increase in holding time can improve the high temperature softening and sealing of glass ceramic materials However, it is necessary to consider the thermal analysis characteristics of the glass ceramic material used and the cell geometry and thickness to adjust the specifications and bonding parameters of the thin strip; according to different cell stack assembly designs, it can be punched and cut into different shapes. Figure 2.

Step 3: The glass-ceramic material in this preferred embodiment is commercial glass-ceramic powder, and the cells used are two sets of self-made anode-supported solid oxide fuel cells, and the thin strip packaging parameters are tested. Sample A is the strip thickness 500μm and high temperature sealing at 880°C for 8 hours; sample B has a thin strip with a thickness of 700μm and high temperature sealing at 850°C for 24 hours.

Step 4: Use the above glass ceramic sealing tape to package the battery stack, which can avoid the thermal stress cracking behavior of the packaging material due to uneven thickness during the high-temperature sealing process due to the difference in the operating time sequence and component geometry during the traditional dispensing and packaging process , Causing stack leakage and cell failure. For the sealing conditions of the thin strip, the thickness of the battery to be assembled and the optimization of the sealing temperature and time must be considered, and the thin strip packaging and the single cell stack invented in this case must be tested and verified.

Step 5: The comparison results of the electrical performance test are shown in Figures 3 and 4, which show that the open circuit voltage of the single cell stack is close to the theoretical standard value (>1.1V). ASC (NiO-YSZ|YSZ|YSZ-LSM|LSM, 430μm,>10×10cm ² ), different strip thicknesses and sealing conditions, the impact on specific specifications of cells must be adjusted and verified to obtain an optimized package parameter. Compared with sample A, the power generation efficiency of sample B is significantly improved by more than 50%.

The single-cell stack packaging of solid oxide fuel cells is based on the prepared sealant dispensing and coating on the components. It is not easy to carry out continuous and large-scale stack packaging operations. At the same time, the thickness of the packaging glue is easy to change due to the coating sequence. The time difference produces uneven thickness and size, causing defects and leakage during high-temperature sealing. The sealing of the battery stack with the thin strip of the present invention has mass production and the sealing glue size can be controlled. Experiments prove that the glass ceramic sealing strip of the present invention has flexibility, stackability, cutting and good formability, and is suitable for batteries of different sizes and geometric shapes. The stack assembly design can achieve an excellent sealing effect by optimizing the sealing ribbon packaging conditions, thereby obtaining a good battery stack power generation efficiency.

The remaining glass-ceramic sealing ribbon after punching and cutting can be re-adjusted to an appropriate ratio and made into the ceramic slurry required for scraper molding, which has the advantages of recyclability and cost reduction. It is proved by the above that the superiority, necessity, innovation and criticality of the production process of the invention have indeed met the requirements for an invention patent application, and a patent application shall be filed in accordance with the law.

S1: Preparation of green glass ceramic sealing strip substrate by scraper forming method

S2: The thin sealing tape is stacked and pressed according to the specifications of the cell used to achieve the target thickness

S3: Cooperate with battery stack assembly for geometric shape cutting, packaging and high temperature pressing procedures

S4: Laminate the sealed glass ceramic thin tape between the cell and the cell stack for cell stack assembly operations

S5: Carry out sealing glass ceramic thin tape package parameter test

S6: Conduct the electrical performance test and comparison results of anode supported solid oxide fuel cells

Claims (7)

A method for manufacturing a glass ceramic sealing ribbon includes the following steps: selecting a glass ceramic material with sealing properties, blending its ceramic powder into a slurry and using a scraper to form the glass ceramic sealing ribbon green embryo, wherein the slurry composition is The glass-ceramic material with sealing properties is the main body, combined with organic solvents, dispersants, plasticizers, pore-forming agents and bonding agents. The weight composition of the slurry component for making the glass-ceramic sealing ribbon green embryo includes the sealing glass-ceramic material 68wt %, methyl ethyl ketone 17wt%, ethanol 7wt%, triethylamine 1.5wt%, dibutyl phthalate 1.0wt%, polyethylene glycol 1.0wt%, polyvinyl butyral film 4.5wt%; the scraper The glass ceramic sealing ribbon green embryo prepared by forming is made by multi-sheet combination and lamination through the heat lamination and water pressure equalization process. The thickness of the single glass ceramic sealing ribbon green embryo is 80 to 200 μm Between; the overall sealing ribbon size is matched with the solid oxide fuel cell sheet to be made into a certain size, and before the stack is sealed and assembled, it is cut into a monolithic cell stack with a mold according to the geometry required for the stack packaging The glass ceramic sealing ribbon kit; the glass ceramic sealing ribbon kit is attached between the cell and the cell stack assembly to perform the battery stack program, and the glass ceramic sealing ribbon kit is attached between the cell and the cell stack assembly to perform the battery The stack assembly process is to perform high temperature softening at 800 to 900°C for 4 to 24 hours and then seal and press; conduct the electrical performance test of the glass ceramic sealing ribbon packaging parameters. The open circuit voltage of the single cell stack reaches 1.1 volts. According to the manufacturing method of the glass ceramic sealing ribbon of claim 1, the number of stacked green sheets of the glass ceramic sealing ribbon is determined by the size of the single green embryo and the size of the battery stack. According to the manufacturing method of the glass ceramic sealing ribbon of claim 1, wherein the overall thickness of the glass ceramic sealing ribbon is between 300 and 800 μm. According to the manufacturing and application method of the glass ceramic sealing ribbon according to claim 1, the size of the overall glass ceramic sealing ribbon is first manufactured with the solid oxide fuel cell sheet to a size of 10×10 cm ² to 15×15 cm ² . According to the method for manufacturing the glass ceramic sealing ribbon according to claim 1, wherein the glass ceramic sealing ribbon kit is attached between the cell and the cell stack assembly to carry out the cell stack assembly procedure at 800 to 900°C for 4 to 24 hours After being softened at high temperature, seal and press. According to claim 1, the glass ceramic sealing ribbon manufacturing method, in which the glass ceramic sealing ribbon packaging parameter test is carried out using two sets of anode-supported solid oxide fuel cell sheets as samples. The thickness of the sample A ribbon is 500μm, and the thickness is 880 The high-temperature sealing was performed at ℃ for 8 hours, and the thickness of the sample B ribbon was 700 μm, and the high-temperature sealing was performed at 850 ℃ for 24 hours to test the sealing parameters of the glass ceramic sealing ribbon. According to the manufacturing method of the glass ceramic sealing ribbon of claim 6, the test thickness of the anode-supported solid oxide fuel cell sheet is 430μm, the size is not less than 10×10cm ² , and the composition is NiO-YSZ|YSZ|YSZ-LSM| LSM.

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