KR20230066892A - Energy generator added by asymmetrically coated two dimensional hygroscopic nanoclay and manufacturing method for the energy generator - Google Patents

Abstract

Disclosed are an energy generator onto which two-dimensional hygroscopic nanoclay is asymmetrically coated and added and a manufacturing method of the energy generator. According to one embodiment, the energy generator includes a hydrophilic fiber membrane which is coated entirely with a carbon layer and has some areas coated asymmetrically with two-dimensional hygroscopic nanoclay. In the hydrophilic fiber membrane, water is applied to an area asymmetrically coated with the two-dimensional hygroscopic nanoclay, thereby generating electrical energy according to a wetting phenomenon of the water.

Description

Energy generator and manufacturing method of energy generator in which two-dimensional hygroscopic nanoclay is asymmetrically coated and added

The following description relates to an energy generator and a manufacturing method of the energy generator to which the two-dimensional hygroscopic nanoclay is asymmetrically coated and added.

Department Name: Industry

Assignment number: SRFC-MA1802-05

Research Project Name: Industrial R&D Project

Title of research project: Development of self-pollination adsorption technology-based energy harvesting system (2021)

Account number: G01210399

Supervisory organization (name of organization performing the project): Korea Advanced Institute of Science and Technology (KAIST)

Research management specialized institution [task management (specialty (name of institution))]: Samsung Electronics Co., Ltd.

Research Period: 2021-07-01 ~ 2021-11-30

Recently, as environmental issues have been highlighted worldwide and facing an energy crisis due to the depletion of fossil fuels, great efforts are being made to develop various alternative energy sources. However, alternative energy sources at the current stage of use have limitations in that they are limitedly used due to limited efficiency and profitability. Recently, technology that produces energy using water that can be easily found around us is in the limelight, and unlike solar cells, piezoelectric power generation, and triboelectric power generation, energy harvesters using water can stably operate without restrictions in specific time, environment, and place. Direct current can be produced. A carbon-based energy harvester using water is formed by asymmetric wetting of a hydrophilic fiber membrane coated with a carbon layer by utilizing an electrical double layer formed in the process of adsorption of a polar solvent on the carbon surface. Energy is generated by the potential difference. However, there is a limit in that energy production cannot be performed when water does not remain in the hydrophilic membrane coated with the carbon layer due to evaporation of water. In order to produce continuous energy by the potential difference formed by the asymmetric wetting of the hydrophilic fiber membrane coated with the carbon layer, the evaporation of water is suppressed without restriction of the surrounding environment, and the water-based energy generator holds water for a long time. It is required to have the skills to do so.

[Prior patent literature]

Korean Patent Publication No. 10-2020-0092236

In order to respond to the energy crisis due to the depletion of fossil fuels, an energy generator using water that can be easily found around as energy power and a manufacturing method of the energy generator are provided.

In order to improve the performance of conventional energy harvesters using water, an eco-friendly, hygroscopic nanoclay is added to provide an energy generator capable of delaying evaporation of water and a manufacturing method of the energy generator.

A two-dimensional hygroscopic nanoclay is asymmetrically positioned on a carbon layer-coated hydrophilic fibrous membrane to provide an energy generator that can generate a high potential difference and current for a long time and a manufacturing method of the energy generator.

It includes a hydrophilic fibrous membrane in which the entire carbon layer is coated, and two-dimensional hygroscopic nanoclay is asymmetrically coated in a partial region, and the region in which the two-dimensional hygroscopic nanoclay is asymmetrically coated is included in the hydrophilic fibrous membrane. It provides an energy generator characterized in that by applying water to generate electrical energy according to the wetting of the water.

According to one side, the hydrophilic fibrous membrane may be characterized in that the two-dimensional hygroscopic nanoclay supports water to delay the water evaporation time.

According to another aspect, the two-dimensional hygroscopic nanoclay is a layered silicate, montmorillonite, hectorite, magadite, kenyaite, kaolinite, saponite (saponite), beidelite, nontronite, vermicullite, swellable mica (mica), synthetic mica (synthetic mica), kanemite (kanemite), smectite (smectite), illite ( illite, chlorite, muscovite, pyrophyllite, antigorite, glauconite, vermiculite, sepiolite, imogolite containing at least one of imogolite, sobockite, nacrite, anauxite, sericite, ledikite, chrysotile and antigorite can be characterized.

According to another aspect, a voltage difference induced by a difference in capacitance between a wet region and a dry region in the hydrophilic fiber membrane coated with the carbon layer as a whole. It can be characterized in that electrical energy is generated by making a.

According to another aspect, the hydrophilic fibrous membrane may be coated by binding hygroscopic nanoclay to the surfaces of individual fibers.

According to another aspect, the amount of water applied may be characterized in that it is included in the range of 0.1 μL or more and 1000 mL or less per time.

According to another aspect, the applied water is HF, LiF, NaF, KF, RbF, HCl, LiCl, NaCl, KCl, RbCl, BeCl ₂ , MgCl 2 , CaCl ₂ , SrCl ₂ , BaCl _{2 ,} HBr, LiBr, It may be characterized in that it includes at least one of NaBr, KBr and RbBr.

According to another aspect, the thickness of the hydrophilic fibrous membrane may be characterized in that it is included in the range of 10 μm to 1 mm.

According to another aspect, the voltage of the electrical energy may be included in the range of 10 μV or more and 100 V or less, and the current of the electrical energy may be included in the range of 1 nA or more and 100 mA or less.

According to another aspect, the carbon layer is a carbon particle selected from Super P, Denka black, acetylene black, or Ketjen black, or activated carbon , It may be characterized in that it is composed of a conductive carbon material including at least one or more of graphene and carbon nanotubes.

A manufacturing method of an energy generator, comprising: (a) cutting a hydrophilic fiber membrane according to a predetermined standard; (b) coating a carbon layer on the surface of cotton fibers by immersing the hydrophilic fiber membrane in a coating solution forming a carbon layer; (c) preparing a hygroscopic nanoclay solution; (d) preparing a mixed solution by mixing the hygroscopic nanoclay solution with the coating solution; and (e) immersing a partial area of the hydrophilic fibrous membrane in the mixed solution to asymmetrically coat the hygroscopic nanoclay to prepare a hydrophilic fibrous membrane coated with the two-dimensional hygroscopic nanoclay asymmetrically. It provides a method of manufacturing an energy generator that does.

In order to respond to the energy crisis due to the depletion of fossil fuels, an energy generator using water that can be easily found around can be provided as energy power.

In order to improve the performance of existing energy harvesters using water, it is eco-friendly and can delay the evaporation of water by adding hygroscopic nanoclay.

A high potential difference and current can be generated for a long time by asymmetrically positioning the two-dimensional hygroscopic nanoclay on a hydrophilic fiber membrane coated with a carbon layer.

Since the two-dimensional hygroscopic nanoclay is a hydrophilic material and is easily dispersed in water, it is easy to uniformly and asymmetrically coat the two-dimensional hygroscopic nanoclay on the surface of the hydrophilic fiber membrane.

Energy production efficiency can be improved as the duration of an asymmetric wetting phenomenon in the hydrophilic fiber membrane coated with the carbon layer increases. For example, it is possible to produce energy for more than 1 hour and 20 minutes with a small amount of water of 0.2 ml, making it possible to use the energy generator as an auxiliary power supply for electronic devices and wearable devices.

The accompanying drawings, which are included as part of the detailed description to aid understanding of the present invention, provide examples of the present invention and explain the technical idea of the present invention together with the detailed description.
1 is a flowchart illustrating an example of a method for manufacturing a water-based energy generator coated with a two-dimensional hygroscopic nanoclay asymmetrically according to an embodiment of the present invention.
2 is a diagram showing an example of a manufacturing process of a water-based energy generator coated with a two-dimensional hygroscopic nanoclay asymmetrically in one embodiment of the present invention.
3 to 6 are scanning electron microscope (Scanning Electron Microscope, SEM) images of a hydrophilic fiber membrane according to a coating process according to an embodiment of the present invention.
7 to 10 are graphs showing power generation characteristics of a water-based energy generator to which a two-dimensional hygroscopic nanoclay is asymmetrically added according to an embodiment of the present invention.

The present invention can apply various transformations and can have various embodiments. Hereinafter, specific embodiments will be described in detail based on the accompanying drawings.

In describing the present invention, if it is determined that a detailed description of related known technologies may obscure the gist of the present invention, the detailed description will be omitted.

Terms such as first and second may be used to describe various components, but the components are not limited by the terms, and the terms are only for the purpose of distinguishing one component from another. used

1 is a flowchart illustrating an example of a method for manufacturing a water-based energy generator coated with a two-dimensional hygroscopic nanoclay asymmetrically according to an embodiment of the present invention. The manufacturing method of the energy generator according to the present embodiment includes cutting the hydrophilic fiber membrane according to a predetermined standard (110), immersing the hydrophilic fiber membrane in a coating solution forming a carbon layer, and coating the carbon layer on the surface of the cotton fiber. Step 120, preparing a hygroscopic nanoclay solution (130), mixing the hygroscopic nanoclay solution with a coating solution to prepare a mixed solution (140), and immersing a part of the hydrophilic fiber membrane in the mixed solution to obtain a hygroscopic A step 150 of preparing a hydrophilic fibrous membrane coated with the two-dimensional hygroscopic nanoclay asymmetrically by asymmetrically coating the nanoclay may be included.

In the step 110 of cutting the hydrophilic fiber membrane according to a preset standard, the preset standard may include a standard in which the horizontal ratio is three or more times the vertical ratio. As a more specific example, the hydrophilic fiber membrane may be cut so that the ratio of width to length is 7:2, 3:1 or 19:6. Meanwhile, the hydrophilic fiber membrane may include, for example, a cotton fiber membrane, but is not limited thereto. For example, the hydrophilic fiber membrane is manufactured using at least one of cotton fabric, mulberry paper, polypropylene membrane, oxygen plasma treated nonwoven fabric, hydrophilic surface treated fabric or nanofiber. It can be.

In the step 120 of coating the carbon layer on the surface of the cotton fiber by immersing the hydrophilic fiber membrane in a coating solution to form a carbon layer, the carbon layer is Super P, Denka black, acetylane black ( acetylene black), carbon particles selected from Ketjen black, or conductive carbon materials including at least one of activated carbon, graphene, and carbon nanotubes. can In the following embodiments, processes for forming a carbon layer using ketjen black are described to aid understanding of the invention, but are not limited thereto. In one embodiment, the content of the ketjen black material included in the coating solution may be included in the range of 0.1 to 10 wt% compared to the water solvent. In addition, the hydrophilic fiber membrane coated with the Ketjen Black layer may have a mesh structure in order to have efficient drying characteristics. In this case, in step 120, the hydrophilic fiber membrane coated with the Ketjen Black layer may be dried in the range of 60 °C to 80 °C. At this time, in step 120, the loading amount of the ketjen black material may be adjusted by adjusting the number of times the hydrophilic fiber membrane is impregnated with the coating solution.

In step 130 of preparing the hygroscopic nanoclay solution, the hygroscopic nanoclay is a layered silicate, montmorillonite, hectorite, magadite, kenyaite, kaolinite , saponite, beidelite, nontronite, vermicullite, swelling mica, synthetic mica, kanemite, smectite, illite, chlorite, muscovite, pyrophyllite, antigorite, glauconite, vermiculite, sepiolite, At least one of imogolite, sobockite, nacrite, anauxite, sericite, ledikite, chrysotile and antigorite can include At this time, the hygroscopic nanoclay content included in the hygroscopic nanoclay solution may be included in the range of 0.1 to 10 wt% compared to the water solvent.

In step 140 of preparing a mixed solution by mixing the hygroscopic nanoclay solution with the coating solution, in one embodiment, after mixing the hygroscopic nanoclay solution with the coating solution, the hygroscopic nanoclay solution is mixed with the coating solution using an ultrasonic device. Mixed solutions can be prepared by dispersing.

In the step 150 of preparing a hydrophilic fiber membrane coated with the two-dimensional hygroscopic nanoclay asymmetrically by immersing a portion of the hydrophilic fiber membrane in a mixed solution and asymmetrically coating the hygroscopic nanoclay, the hydrophilic fiber membrane A partial area of may be an area included in the range of 1% to 50% of the total area of the hydrophilic fibrous membrane. At this time, in step 150, the loading amount of the hygroscopic nanoclay material may be adjusted by adjusting the number of times the hydrophilic fiber membrane is impregnated with the mixed solution. As already described, the hydrophilic fibrous membrane coated with the Ketjen Black layer may have a mesh structure to have efficient drying characteristics, and in step 150, the hydrophilic two-dimensional hygroscopic nanoclay is asymmetrically coated. The fibrous membrane can be dried in the range of 60°C to 80°C. The hydrophilic fiber membrane may be coated with hygroscopic nanoclay bound to the surface of each fiber.

Through the manufacturing method of the energy generator of FIG. 1, the carbon layer is entirely coated, and the two-dimensional hygroscopic nanoclay includes a hydrophilic fiber membrane coated in a partial area asymmetrically, and the hydrophilic fiber membrane has a two-dimensional shape. An energy generator characterized in that water is applied to the area coated with hygroscopic nanoclay asymmetrically to generate electric energy according to the wetting of water can be manufactured.

At this time, the hydrophilic fibrous membrane can delay the water evaporation time by itself due to its hydrophilicity, but the coated two-dimensional hygroscopic nanoclay can hold water, thereby further delaying the water evaporation time.

On the other hand, in an energy generator, a voltage difference induced by a difference in capacitance between a wet region and a dry region in a hydrophilic fiber membrane coated with a carbon layer as a whole is created. Electrical energy can be generated. To this end, the amount of water applied may be in the range of 0.1 μL or more and 1000 mL or less per time. In addition, the thickness of the hydrophilic fibrous membrane may be included in the range of 10 μm to 1 mm.

The voltage of the generated electrical energy may be included in the range of 10 μV or more and 100 V or less, and the current may be included in the range of 1 nA or more and 100 mA or less.

When the two-dimensional hygroscopic nanoclay is included in an amount of 10 wt% or more compared to the water solvent, it is difficult to disperse in the water solvent, and when coating on the hydrophilic fiber membrane, the nanoclay may stick together. In addition, when mixing and dispersing the two-dimensional hygroscopic nanoclay and Ketjen Black, if the ultrasonic device is not sufficiently dispersed, agglomeration between particles may occur. In addition, when the amount of water applied to the energy generator coated with the two-dimensional hygroscopic nanoclay and the carbon layer (eg, Ketjen Black) is less than 0.02 ml, the wet region and the dry region There may be a problem that electrical energy is not generated because a sufficient capacitance difference is not generated between the two layers.

2 is a diagram showing an example of a manufacturing process of a water-based energy generator coated with a two-dimensional hygroscopic nanoclay asymmetrically in one embodiment of the present invention. Figure 2 shows the process of preparing a cotton fiber membrane entirely coated with the ketjen black solution by immersing the cotton fiber membrane in the ketjen black solution, and then drying it. In addition, Figure 2 shows the process of preparing a mixed solution of hygroscopic nanoclay, then partially supporting the dried cotton fiber membrane to prepare a cotton fiber membrane asymmetrically coated with hygroscopic nanoclay, and drying it again. .

Example 1: Preparation of water-based energy generator coated with two-dimensional hygroscopic nanoclay asymmetrically

In order to manufacture the energy generator according to Example 1, first, a cotton fiber membrane was prepared by cutting to a standard of 20 mm (length) × 70 mm (width). In addition, to prepare a ketjen black solution, 0.1 g of ketjen black and 0.2 g of a surfactant (sodium dodecylbenzenesulfonate, SDBS) were mixed with 20 ml of deionized water in an 80 mL transparent container, and then mixed evenly through sonication. and dispersed. Thereafter, the cut cotton fiber membrane was immersed once in a solution in which ketjen black was dispersed, and then put on a mesh and dried in a drying oven at 60 ° C.

In addition, in order to prepare a hygroscopic nanoclay solution, 0.01 g of montmorillonite (MMT) was mixed with 20 ml of deionized water in an 80 mL transparent container and sufficiently stirred at 80 ° C. and 300 rpm. Thereafter, the ketjen black solution prepared in the above manner and the nanoclay solution well dispersed in distilled water are mixed in a transparent container of 80 mL, and then evenly mixed and dispersed through sonication to prepare a mixed solution in which hygroscopic nanoclay and ketjen black are dispersed. did

Thereafter, a portion (for example, half) of the cotton fiber membrane dried after being immersed once in the ketjen black solution was immersed once in a mixed solution in which hygroscopic nanoclay and ketjen black were dispersed, and then put on a mesh and dried at 60 ° C. Finally, a water-based energy generator coated with two-dimensional hygroscopic nanoclay was fabricated by drying in an oven.

3 to 6 are scanning electron microscope (Scanning Electron Microscope, SEM) images of a hydrophilic fiber membrane according to a coating process according to an embodiment of the present invention. Figure 3 is a scanning electron microscope image of a cotton fiber membrane, Figure 4 is a scanning electron microscope image of a cotton fiber membrane coated with Ketjen Black, Figure 5 is a scanning electron microscope image of a cotton fiber membrane coated with hygroscopic nanoclay, 6 shows scanning electron microscope images of cotton fiber membranes coated with both hygroscopic nanoclay and Ketjen Black, respectively. It can be seen that the difference between the image of FIG. 6 of the cotton fiber membrane coated with the Ketjen Black solution and the hygroscopic nanoclay and the image of FIG. 4 of the normal cotton fiber membrane without any coating on the cotton fiber membrane. In addition, when mixing and coating the hygroscopic nanoclay and ketjen black, it can be confirmed that the hygroscopic nanoclay and ketjen black are coated on individual fibers of the cotton fiber membrane, as shown in FIGS. 4 and 5, respectively.

Meanwhile, in order to evaluate the power generation characteristics of the fabricated energy generator, 0.2 ml of deionized water was dropped on the area where the hygroscopic nanoclay was asymmetrically coated in the energy generator. At this time, open circuit voltage and short circuit voltage characteristics were evaluated using a potentiostat.

7 to 10 are graphs showing power generation characteristics of a water-based energy generator to which a two-dimensional hygroscopic nanoclay is asymmetrically added according to an embodiment of the present invention.

The graph of FIG. 7 shows that the energy generator coated with hygroscopic nanoclay (MMT) asymmetrically has an increased energy (voltage) production duration compared to the conventional energy generator for comparison (Reference).

The graph of FIG. 8 shows that the energy (current) production duration is increased in the energy generator coated with hygroscopic nanoclay (MMT) asymmetrically compared to the conventional energy generator (Reference) for comparison.

Comparative Example 1: Hydrophobic surface-modified hygroscopic nanoclay and cotton fiber membrane-based energy generator coated with Ketjen Black

In Comparative Example 1, the surface of the hygroscopic nanoclay was modified with a polymer having hydrophobic properties using a well-known method. Then, as in Example 1 described above, after immersing once in a solution in which Ketjen Black is dispersed, a dried cotton fiber membrane is prepared, and a mixed solution is prepared using hygroscopic nanoclay whose surface is hydrophobically modified, A cotton fiber membrane was immersed once in a solution in which only half of the hydrophobic surface-modified nanoclay and Ketjen Black were dispersed and dried to finally fabricate a water-based energy generator to which the two-dimensional hygroscopic nanoclay was added.

9 and 10 show open-circuit voltage and short-circuit current characteristics of the energy generator of Example 1 and the energy generator of Comparative Example 1. Looking at the graphs of FIGS. 9 and 10, compared to the increase in the energy (voltage, current) production duration in the energy generator coated with the asymmetrically hygroscopic nanoclay (MMT), the nanoclay (Modified MMT) ), it can be confirmed that the duration of energy (voltage, current) production is reduced due to a decrease in water bearing capacity. This may conversely mean that the duration of energy (voltage, current) production increases due to the water-bearing ability of the hygroscopic nanoclay.

In this way, according to embodiments of the present invention, it is possible to provide an energy generator using water that can be easily found around as energy power in order to respond to an energy crisis due to depletion of fossil fuels. In addition, in order to improve the performance of existing energy harvesters using water, it is environmentally friendly and can delay the evaporation of water by adding hygroscopic nanoclay. In addition, a high potential difference and current can be generated for a long time by asymmetrically positioning the two-dimensional hygroscopic nanoclay on the hydrophilic fiber membrane coated with the carbon layer. In addition, since the two-dimensional hygroscopic nanoclay is a hydrophilic material and is easily dispersed in water, it is easy to uniformly and asymmetrically coat the two-dimensional hygroscopic nanoclay on the surface of the hydrophilic fiber membrane. In addition, energy production efficiency can be improved as the duration of an asymmetric wetting phenomenon in the hydrophilic fiber membrane coated with the carbon layer increases. For example, it is possible to produce energy for more than 1 hour and 20 minutes with a small amount of water of 0.2 ml, making it possible to use the energy generator as an auxiliary power supply for electronic devices and wearable devices.

As described above, although the embodiments have been described with limited examples and drawings, those skilled in the art can make various modifications and variations from the above description. For example, the described techniques may be performed in an order different from the method described, and/or components of the described system, structure, device, circuit, etc. may be combined or combined in a different form than the method described, or other components may be used. Or even if it is replaced or substituted by equivalents, appropriate results can be achieved.

Therefore, other implementations, other embodiments, and equivalents of the claims are within the scope of the following claims.

Claims (20)

A hydrophilic fibrous membrane coated entirely with a carbon layer and asymmetrically coated with two-dimensional hygroscopic nanoclay in some areas.
including,
An energy generator characterized in that in the hydrophilic fiber membrane, electric energy is generated according to the wetting of water by applying water to the area where the two-dimensional hygroscopic nanoclay is asymmetrically coated. According to claim 1,
The hydrophilic fibrous membrane is an energy generator, characterized in that the two-dimensional hygroscopic nanoclay supports water to delay the time for water to evaporate. According to claim 1,
The two-dimensional hygroscopic nanoclay is a layered silicate, and is composed of montmorillonite, hectorite, magadite, kenyaite, kaolinite, saponite, Beidelite, nontronite, vermicullite, swellable mica (mica), synthetic mica, kanemite, smectite, illite, chlorite chlorite, muscovite, pyrophyllite, antigorite, glauconite, vermiculite, sepiolite, imogolite, sobok An energy generator comprising at least one of sobockite, nacrite, anauxite, sericite, ledikite, chrysotile and antigorite . According to claim 1,
In the hydrophilic fiber membrane coated with the carbon layer as a whole, electric energy is generated by creating a voltage difference induced by a difference in capacitance between a wet region and a dry region. An energy generator characterized in that being. According to claim 1,
The hydrophilic fiber membrane is an energy generator, characterized in that the hygroscopic nanoclay is bound and coated on the surface of each fiber. According to claim 1,
The energy generator, characterized in that the amount of the applied water is included in the range of 0.1 μL or more and 1000 mL or less per time. According to claim 1,
The applied water is selected from among HF, LiF, NaF, KF, RbF, HCl, LiCl, NaCl, KCl, RbCl, BeCl ₂ , MgCl ₂ , CaCl ₂ , SrCl ₂ , BaCl ₂ , HBr, LiBr, NaBr, KBr and RbBr. An energy generator comprising at least one. According to claim 1,
The energy generator, characterized in that the thickness of the hydrophilic fiber membrane is included in the range of 10 μm to 1 mm. According to claim 1,
The voltage of the electric energy is included in the range of 10 μV or more and 100 V or less,
The current of the electric energy is included in the range of 1 nA or more and 100 mA or less
An energy generator characterized by a. According to claim 1,
The carbon layer is a carbon particle selected from Super P, Denka black, acetylene black, or Ketjen black, activated carbon, or graphene. and carbon nanotubes. In the manufacturing method of the energy generator,
(a) cutting the hydrophilic fiber membrane according to a predetermined standard;
(b) coating a carbon layer on the surface of cotton fibers by immersing the hydrophilic fiber membrane in a coating solution forming a carbon layer;
(c) preparing a hygroscopic nanoclay solution;
(d) preparing a mixed solution by mixing the hygroscopic nanoclay solution with the coating solution; and
(e) preparing a hydrophilic fibrous membrane coated with a two-dimensional hygroscopic nanoclay asymmetrically by immersing a partial region of the hydrophilic fibrous membrane in the mixed solution and asymmetrically coating the hygroscopic nanoclay.
A method of manufacturing an energy generator comprising a. According to claim 11,
In step (a),
The predetermined standard is a method of manufacturing an energy generator, characterized in that it includes a standard in which the horizontal ratio is three times or more than the vertical ratio. According to claim 11,
The carbon layer includes a Ketjen Black layer,
In step (b),
The content of the ketjen black material contained in the coating solution is included in the range of 0.1 to 10 wt% compared to the water solvent
Method for manufacturing an energy generator, characterized in that. According to claim 11,
The carbon layer includes a Ketjen Black layer,
The hydrophilic fiber membrane coated with the Ketjen Black layer has a mesh structure to have efficient drying characteristics,
In step (b),
Drying the hydrophilic fiber membrane coated with the ketjen black layer in the range of 60 ° C to 80 ° C
Method for manufacturing an energy generator, characterized in that. According to claim 11,
The carbon layer includes a Ketjen Black layer,
In step (b),
Adjusting the loading amount of the ketjen black material by controlling the number of times the hydrophilic fiber membrane is impregnated with the coating solution
Method for manufacturing an energy generator, characterized in that. According to claim 11,
In step (c),
The method of manufacturing an energy generator, characterized in that the hygroscopic nanoclay content contained in the hygroscopic nanoclay solution is in the range of 0.1 to 10 wt% compared to the water solvent. According to claim 11,
In step (d),
After mixing the hygroscopic nanoclay solution with the coating solution, the energy generator manufacturing method, characterized in that for producing the mixed solution by dispersing the hygroscopic nanoclay solution in the coating solution using an ultrasonic device. According to claim 11,
In step (e),
The method of manufacturing an energy generator, characterized in that the partial area of the hydrophilic fibrous membrane is an area included in the range of 1% to 50% of the total area of the hydrophilic fibrous membrane. According to claim 11,
In step (e),
Method for producing an energy generator, characterized in that by adjusting the number of times the hydrophilic fiber membrane is impregnated with the mixed solution to control the loading amount of the hygroscopic nanoclay material. According to claim 11,
The carbon layer includes a Ketjen Black layer,
The hydrophilic fiber membrane coated with the Ketjen Black layer has a mesh structure to have efficient drying characteristics,
In step (e),
Drying the hydrophilic fibrous membrane asymmetrically coated with the two-dimensional hygroscopic nanoclay in the range of 25 ° C to 120 ° C
Method for manufacturing an energy generator, characterized in that.

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