KR20200129064A - Triboelectric energy harvester, method of manufacturing of the same, method of operationg of the same, e-paper and electronic sensor using the same - Google Patents

Abstract

A triboelectric energy harvester according to an embodiment of the present invention comprises: a first film including a first silver nanowire layer and a first cellulose nano fiber layer; a second film including a second silver nanowire layer; and a connector to electrically connect the first film with the second film. When the first cellulose nano fiber layer approaches and frictions the second silver nanowire layer, the first cellulose nano fiber layer is charged as a cathode and the second silver nanowire layer is charged as an anode. The first film is manufactured by a step of obtaining a filter film formed therein with a silver nanowire layer by filtering the silver nanowire solution through a filter film; a step of obtaining a filter film further formed therein with a cellulose nano fiber layer by filtering cellulose solution in a filter film formed therein with the silver nanowire layer; and a step of obtaining the first film by removing the filter film from the filter film further formed therein with the cellulose nano fiber layer. An intensity of a current flowing through the connector corresponds to density of a silver nanowire in the silver nanowire solution or at least one of degree of dispersion and pressure of the cellulose nano fiber.

Description

A triboelectric energy harvester, a method of manufacturing the triboelectric energy harvester, an operation method of the triboelectric energy harvester, an electronic paper and an electronic sensor using the triboelectric energy harvester TECHNICAL FIELD OF THE SAME, E-PAPER AND ELECTRONIC SENSOR USING THE SAME}

The present invention relates to a triboelectric energy harvester, a method of manufacturing the triboelectric energy harvester, a method of operating the triboelectric energy harvester, and an electronic paper and an electronic sensor using the triboelectric energy harvester.

This study was prepared with the support of the 2017 Pusan National University Hospital Institute of Convergence Medicine Research Project Research Fund (CMIT 2017-00).

Energy harvesting (which can also be referred to as energy harvesting, or energy harvesting) refers to a method or technique for collecting external energy by a predetermined method and converting it into electrical energy. Energy harvester (energy harverster) refers to an electronic or mechanical device capable of performing such energy harvesting. For example, the energy harvester may convert solar energy, kinetic energy of a human body, or the like into corresponding electric energy according to the characteristics of the device, and use or store it. Such energy harvesting technology is in the spotlight as an eco-friendly energy technology because it is possible to secure energy without using fossil fuel combustion or nuclear power generation.

Recently, energy harvesting technology using various physical phenomena is being introduced. For example, a technology that acquires electrical energy (thermoelectric effect) by using the temperature difference of an object, a technology that obtains electrical energy by applying vibration to a piezoelectric element (piezoelectric effect), a technology that acquires electrical energy using solar heat, and / Or, a technique for obtaining electrical energy by using static electricity generated by friction (Triboelectric effect) has been introduced.

A problem to be solved to provide a triboelectric energy harvester having excellent performance and high stability electrical output while being easily manufactured at a low cost at a low cost, a method of manufacturing the triboelectric energy harvester, and a method of operating the triboelectric energy harvester To

In addition, it is another object to be solved to provide an electronic paper and an electronic sensor applicable to various fields using the above-described triboelectric energy harvester.

The triboelectric energy harvester according to an embodiment of the present invention includes a first film including a first silver nanowire layer and a first cellulose nanofiber layer, a second film including a second silver nanowire layer, and the first film and It includes a connection part for electrically connecting the second film, and when the first cellulose nanofiber layer approaches and rubs against the second silver nanowire layer, the first cellulose nanofiber layer is charged as a negative electrode in response thereto, and the The second silver nanowire layer is charged as an anode, and the first film is obtained by filtering a silver nanowire solution through a filtration film to obtain a filtration film having a silver nanowire layer formed thereon. Obtaining a filtration film further formed with a cellulose nanofiber layer by filtering through a filtration film having a wire layer formed thereon, and removing the filtration film from the filtration film further formed with the cellulose nanofiber layer to obtain the first film; The intensity of the electric current flowing through the connection part corresponds to the concentration of the silver nanowires in the silver nanowire solution or corresponds to at least one of the degree of dispersion and the pressure of the cellulose nanofibers.

Here, the connection part electrically connects the first silver nanowire layer and the second silver nanowire layer to each other, and one surface of the first cellulose nanofiber layer of the first film is, the first silver nanowire A layer in contact with the layer, and the other side of the first cellulose nanofiber layer of the first film faces the second silver nanowire layer of the second film, and the first cellulose nanofiber layer is the second silver nanowire layer When departed from, current from the second silver nanowire layer to the first silver nanowire layer moves through the connection part.

In addition, the current may flow through the first silver nanowire layer until the first cellulose nanofiber layer and the first silver nanowire layer are in equilibrium with each other.

The method of manufacturing a triboelectric energy harvester according to an embodiment of the present invention includes the steps of obtaining a first film, obtaining a second film, and electrically connecting the first film and the second film, and arranging them side by side. Including the step, wherein the step of obtaining the first film, filtering the first silver nanowire solution through a first filtration film to obtain a filtration film on which the first silver nanowire layer is formed, the first cellulose Filtering the solution through the filter film on which the first silver nanowire layer is formed to obtain a filter film on which the first cellulose nanofiber layer is further formed, and the first filter film in the filter film on which the first cellulose nanofiber layer is further formed And removing the to obtain the first film.

The electronic paper according to an embodiment of the present invention includes a first film including a first silver nanowire layer and a first cellulose nanofiber layer, and a second silver nanowire layer having one side facing the first cellulose nanofiber layer. A second film and a connection part electrically connecting the first film and the second film, and when the first cellulose nanofiber layer approaches and rubs against the second silver nanowire layer, the first cellulose The nanofiber layer is charged as a negative electrode, the second silver nanowire layer is charged as a positive electrode, and when the first cellulose nanofiber layer is separated from the second silver nanowire layer, the second silver nanowire layer is 1 A current to the silver nanowire layer is generated, and the first film is obtained by filtering a silver nanowire solution through a filtration film to obtain a filtration film on which a silver nanowire layer is formed. Obtaining a filtration film further formed with a cellulose nanofiber layer by filtering through a filtration film having a wire layer formed thereon, and removing the filtration film from the filtration film further formed with the cellulose nanofiber layer to obtain the first film; It is manufactured through, and the second film includes a second cellulose nanofiber layer formed on the other surface of the second silver nanowire layer facing the one surface.

Here, the connection part electrically connects the first silver nanowire layer and the second silver nanowire layer to each other, and one surface of the first cellulose nanofiber layer of the first film is, the first silver nanowire In contact with the layer, the other side of the first cellulose nanofiber layer of the first film faces the second silver nanowire layer of the second film.

In addition, the electronic paper according to an embodiment of the present invention displays an image or blocks the image display according to a pressure of a pressurized body applied to at least one of the first film and the second film.

According to the above-described triboelectric energy harvester, the method of manufacturing the triboelectric energy harvester, and the operation method of the triboelectric energy harvester, it has ease of manufacturing, low cost in manufacturing, light weight, high stability and/or high performance. It is possible to implement, build, obtain and/or use triboelectric energy harvesters.

The above-described triboelectric energy harvester, the method of manufacturing the triboelectric energy harvester and the operation method of the triboelectric energy harvester, and the electronic paper and electronic sensor using the triboelectric energy harvester include electronic devices, mechanical devices, equipment, structures, and / Or it can be applied to various devices in various industrial fields such as architecture.

According to the above-described triboelectric energy harvester and the method of manufacturing the triboelectric energy harvester, an effect of implementing or developing a simpler structure and a lightweight electronic paper and an electronic sensor can be obtained.

According to the electronic sensor using the above-described triboelectric energy harvester, it is possible to implement various types of sensors without external power such as a battery, thereby reducing manufacturing cost, reducing the thickness or volume of parts and finished products, or reducing the weight of parts or finished products. You can get effects such as weight loss.

1 is a diagram of an embodiment of a triboelectric energy harvester.
2 is a perspective view of an embodiment of a triboelectric energy harvester.
3 is a perspective view for explaining an embodiment of a triboelectric energy harvester including a first film and a second film.
4 is a front view for explaining an embodiment of a first film and a second film.
5 is an exploded perspective view for explaining an embodiment of a first film and a second film.
6 is a first diagram for explaining the operation of the triboelectric energy harvester.
7 is a second diagram for explaining the operation of the triboelectric energy harvester.
8 is a third diagram for explaining the operation of the triboelectric energy harvester.
9 is a fourth diagram for explaining the operation of the triboelectric energy harvester.
10 is a first diagram for explaining a manufacturing process of each film of a triboelectric energy harvester.
11 is a second diagram for explaining the manufacturing process of each film of the triboelectric energy harvester.
12 is a third diagram for explaining the manufacturing process of each film of the triboelectric energy harvester.
13 is a conceptual diagram for an embodiment of an electronic paper.
14 is a diagram for explaining an embodiment of an operation of an electronic paper.
15 is a conceptual diagram of an electronic sensor according to an embodiment.
16 is a diagram illustrating an example of an operation of an electronic sensor that detects folding.

In the following specification, the same reference numerals refer to the same elements unless otherwise specified. The term "unit" used below may be implemented as software or hardware, and according to an embodiment, the term "unit" is implemented as one part, or one "unit" is implemented as a plurality of parts. It is also possible.

When a part is said to be connected to another part throughout the specification, it may mean a physical connection depending on the part and another part, or may mean electrically connected. In addition, when a part includes another part, this does not exclude another part other than the other part unless otherwise stated, and it means that another part may be included further according to the designer's choice. do.

Terms such as first and second are used to distinguish one part from another, and unless otherwise specified, they do not mean sequential expressions. In addition, expressions in the singular may include plural expressions unless there is a clear exception in context.

Hereinafter, various embodiments of a triboelectric energy harvester will be described with reference to FIGS. 1 to 5.

1 is a diagram of an embodiment of a triboelectric energy harvester.

Referring to FIG. 1, the triboelectric energy harvester 1 is, in one embodiment, a first film 10, a second film 20, a first film 10, and a second film. It may include a connection part 30 for electrically connecting the (20).

Each of the first film 10 and the second film 20 is implemented in the shape of a thin film, and the two thin films are spaced apart from each other by a certain distance and may be arranged in a generally parallel alignment. That is, the first film 10 and the second film 20 may be disposed so that normals to the two thin films are substantially parallel.

The first film 10 and the second film 20 may be provided to be able to approach and contact each other according to the environment. In addition, the first film 10 and the second film 20 are provided to be separated and spaced apart from each other depending on the environment even after being in contact. For example, when an external force is applied to all or part of the first film 10, all or part of the first film 10 approaches the second film 20 according to the external force, and the first film 10 ) Comes in contact with all or part of the second film 20 corresponding to all or part of the ). In addition, the first film 10 is separated from each other and separated from the second film 20 when such an external force is removed or when an external force in a direction opposite to the direction applied during contact is applied. This is the same even when an external force is applied to the second film 20, an external force is removed, or an external force in the opposite direction is applied.

The first film 10 may include a first electrode material 11 and a first charging material 12.

When the first charging material 12 is charged, the first electrode material 11 may discharge and transfer electric charges in the first electrode material 11 to the outside according to the polarity of the first charging material 12. In addition, the first electrode material 11 may receive electric charges provided from the outside as needed. For example, when the second charging material 22 is charged, the charge discharged from the second electrode material 21 may be received in response thereto. Further, the first electrode material 11 may be charged according to friction with the second charging material 22. For example, the first electrode material 12 may provide electric charge to the second charging material 22 according to friction and may have a polarity.

According to an embodiment, the first electrode material 12 may include silver nanowires.

The first charging material 12 is provided to be charged according to friction with other external materials. In this case, the first charged material 11 has positive or negative polarity depending on the type of the material constituting the first charged material 11 and the type of the target material to which the first charged material 11 is rubbed. Will have. According to an embodiment, the first charging material 12 may be charged by rubbing against the second electrode material 21 of the second film 20. In this case, for easy friction with the second electrode material 21, the first charging material 12 may be provided to be generally exposed in the direction of the second electrode material 21 of the second film 20. .

According to an embodiment, the first charging material 12 may include cellulose nanofibers. Cellulose nanofibers have a predetermined polarity (eg, negative polarity) according to friction with other materials (eg, silver nanowires). In more detail, for example, cellulose nanofibers may be charged to a negative electrode by obtaining electric charges from silver nanowires according to friction, and silver nanowires may be charged as positive electrodes on the contrary. Therefore, when the first charged material 12 is a cellulose nanofiber, and the object to be rubbed against it (for example, the second charged material 21) is a silver nanowire, the first charged material 12 is used as a negative electrode. It will be charged.

The first electrode material 11 and the first charging material 12 may be formed separately in one film 10 or may be formed by mixing. When formed separately in one film, the first electrode material 11 and the first charging material 12 may be implemented as different layers, respectively. For example, a first electrode material layer (111 in FIG. 3) made of the first electrode material 11 and a first charged material layer (112 in FIG. 3) made of the first charging material 12 are formed of the first film ( It may be formed within 10).

The second film 20 may include a second electrode material 21 and a second charging material 22.

According to an embodiment, the second electrode material 22 may include silver nanowires in the same manner as the first electrode material 11.

The second electrode material 21 discharges charges in the second electrode material 21 to the outside according to the polarity of the second charging material 22 and/or outside (for example, the first electrode material 11 )).

The second electrode material 21 may rub against the first charging material 12 of the first film 10 and may be charged to a predetermined anode or cathode by friction. For example, when the first charged material 12 is a cellulose nanofiber and the second electrode material 22 is a silver nanowire, it is caused by friction between the first charged material 12 and the second electrode material 22. Thus, the nanowire, which is the first electrode material 12, may provide electric charge to the second charging material 22 and have a positive polarity. In this case, the second electrode material 21 may be formed generally in the direction of the first charged material 12 of the first film 20 for easy friction with the first charged material 12.

When the second charging material 22 rubs against other external materials, the second charging material 22 may be charged as a cathode or an anode. According to an embodiment, the second charging material 22 may include cellulose nanofibers in the same manner as the first charging material 12.

As described above, the second electrode material 21 and the second charging material 22 may be separately formed in one film 20 or may be formed by mixing. When the second electrode material 21 and the second charging material 22 are separately formed in the second film 20, the second film 20 is a second electrode material including the second electrode material 21. A layer (121 in FIG. 3) and a second charging material layer (122 in FIG. 3) including a second charging material 22 may be included.

The connection part 30 electrically connects the first electrode material 11 and the second electrode material 21 to transfer current from one of the first electrode material 11 and the second electrode material 21 to the other. It can be done (in other words, the charge is transferred). The connection part 30 may be directly connected to each of the first electrode material 11 and the second electrode material 21, or the first electrode material 11 and the second electrode material via other conductive elements. It may be indirectly connected to at least one of (21).

The connection part 30 may be implemented using a predetermined metal material capable of energization or other material that performs the same or similar function. For example, the connection part 30 may include a metal wire such as a predetermined metal cable or a circuit board.

Hereinafter, based on an embodiment in which the first electrode material 11 and the second electrode material 21 are silver nanowires, and the first charging material 21 and the second charging material 22 are cellulose nanofibers, triboelectric charging energy An example of the harvester 100 will be described.

FIG. 2 is a perspective view illustrating an embodiment of a triboelectric energy harvester, and FIG. 3 is a perspective view illustrating an exemplary embodiment of a triboelectric energy harvester including a first film and a second film. FIG. 4 is a front view illustrating an embodiment of a first film and a second film, and FIG. 5 is an exploded perspective view illustrating an embodiment of a first film and a second film. In describing the triboelectric energy harvester 100 with reference to FIGS. 2 to 5, the direction toward the upper side of the drawing is expressed as an upward direction, and the direction toward the lower side of the drawing is expressed as a downward direction. This does not mean that the triboelectric energy harvester 100 has a special direction.

As shown in FIG. 2, the triboelectric energy harvester 100 includes a plurality of films, that is, a first film 110 and a second film 120, and a connection portion connecting the plurality of films 110 and 120 It may include (130).

The first film 110 and the second film 120 may be the same film. That is, the first film 110 and the second film 120 may include the same material and may have the same structure or shape.

The first film 110 and the second film 120 may be disposed substantially parallel to each other. That is, the first film 110 and the second film 120 may be disposed so that the normal line of the first film 110 and the normal line of the second film 120 are substantially parallel to each other. In this case, the distance d between a point of the first film 110 and a point of the second film 120 corresponding thereto is substantially the same or approximated. Of course, depending on the embodiment, the first film 110 and the second film 120 may not be parallel to each other according to their shape. For example, the first film 110 may be curved to protrude downward or upward, and the second film 120 may be curved to protrude upward or downward. The form in which the first film 110 and the second film 120 are arranged may be variously determined according to a designer's arbitrary selection.

3 to 5, the first film 110 may include a first silver nanowire layer 111 and a first cellulose nanofiber layer 112 stacked on each other. The first silver nanowire layer 111 includes silver nanowires, and the first cellulose nanofiber layer 112 includes cellulose nanofibers. In this case, the first silver nanowire layer 111 is formed in an upward direction relative to the first cellulose nanofiber layer 112, and the first cellulose nanofiber layer 112 is a first silver nanowire layer 111 ) Can be formed in the downward direction relative to. The first silver nanowire layer 111 and the first cellulose nanofiber layer 112 may be installed in contact with or close to each other. Accordingly, the lower surface 111b of the first silver nanowire layer 111 is in contact with or close to the upper surface 112a of the first cellulose nanofiber layer 112.

The second film 120 may include a second silver nanowire layer 121 and a second cellulose nanofiber layer 122 stacked on each other. Like the first film 110, the second silver nanowire layer 1211 includes silver nanowires, and the second cellulose nanofiber layer 122 includes cellulose nanofibers. The second silver nanowire layer 121 and the second cellulose nanofiber layer 122 are installed in contact with or close to each other, but the second silver nanowire layer 121 is relatively upward, and the second cellulose nanofiber The layer 122 may be formed in a relatively downward direction. In other words, the lower surface 121b of the second silver nanowire layer 121 faces the upper surface 122a of the second cellulose nanofiber layer 122 and is on the upper surface 122a of the second cellulose nanofiber layer 122 It is formed in contact or close to it.

As described above, when the first film 110 and the second film 120 are arranged vertically in approximately parallel, the lower surface 112b of the first cellulose nanofiber layer 112 is the second film 120 It is directed toward the disposed direction (more specifically, the top surface 121a of the second silver nanowire layer 121), and the top surface 121a of the second silver nanowire layer 121 is It is directed toward the lower surface 112b of the first cellulose nanofiber layer 112. In this case, the upper surface 111a of the first silver nanowire layer 111 faces in a direction opposite to the direction in which the second film 120 is disposed (ie, upward direction), and the second cellulose nanofiber layer 122 The bottom surface 122b faces a direction opposite to the direction in which the first film 110 is disposed (ie, downward direction).

The connection part 130 may be electrically connected to the first silver nanowire layer 111, and may also be electrically connected to the second silver nanowire layer 121. Accordingly, the connection part 130 electrically connects the first silver nanowire layer 111 and the second silver nanowire layer 121 so that electric charges can be transferred to each other.

Hereinafter, an embodiment of the operation of the triboelectric energy harvester described above will be described with reference to FIGS. 6 to 9.

6 is a first diagram for explaining the operation of the triboelectric energy harvester, and FIG. 7 is a second diagram for explaining the operation of the triboelectric energy harvester. 8 is a third diagram for explaining the operation of the triboelectric energy harvester, and FIG. 9 is a fourth diagram for explaining the operation of the triboelectric energy harvester.

As illustrated in FIG. 6, the first film 110 and the second film 120 of the triboelectric energy harvester 100 may come into contact with each other when an external force 141 or the like is applied. In other words, all or part of the first cellulose nanofiber layer 112 of the first film 110 comes into contact with all or part of the second silver nanowire 121 of the second film 120 corresponding thereto. . More specifically, all or part of the lower surface 112b of the first cellulose nanofiber layer 112 of the first film 110 is all or part of the upper surface 121a of the second silver nanowire layer 121 Come into contact with it. In this case, the contact between the first film 110 and the second film 120 or an additional movement of at least one of the first film 110 and the second film 120 (for example, before, after, left, and / Or movement in the right direction, etc.), friction occurs between the first film 110 and the second film 120. Specifically, friction occurs between all or part of the first cellulose nanofiber layer 112 of the first film 110 and all or part of the second silver nanowire 121 of the second film 120 corresponding thereto. do. The friction between them 112 and 121 charges the cellulose nanofibers of the first cellulose nanofiber layer 112 of the first film 110 to the negative electrode. Accordingly, the first cellulose nanofiber layer 112 is generally charged as a negative electrode. Conversely, the second silver nanowire layer 121 rubbed against the first cellulose nanofiber layer 112 is charged with an anode.

As shown in FIG. 7, the first film 110 and the second film 120 may be separated from each other according to the surrounding environment. For example, the first film 110 and the second film 120 may be separated from each other according to the release force 142 applied from the outside or the elastic force of the first film 110 and the second film 120. have.

During this separation process, the equilibrium of electric charges in the first film 110 is broken. Accordingly, the first silver nanowire layer 111 of the first film 110 emits negative charges (eg, electrons) to the outside until it becomes an equilibrium state. In other words, as the first cellulose nanofiber layer 112 is charged to the negative electrode, the first silver nanowire layer 111 is discharged to the outside through the connection portion 130. The charge transferred to the connection part 130 is transferred to the second silver nanowire layer 121 of the second film 120, and accordingly, from the second silver nanowire layer 121 to the first silver nanowire layer 111 Current flows.

In this case, the intensity of the current transferred from the second silver nanowire layer 121 to the first silver nanowire layer 111 may depend on the amount of silver nanowires in the second silver nanowire layer 121. . In other words, as the amount of nanowires present in the second silver nanowire layer 121 increases, the number of silver nanowires rubbing against the first cellulose nanofiber layer 112 increases, so that more current is applied to the connection part 130 ) Flow through.

In addition, the intensity of the current transferred from the second silver nanowire layer 121 to the first silver nanowire layer 111 may be changed according to the degree of dispersion of the cellulose nanofibers.

In addition, the intensity of the current transmitted from the second silver nanowire layer 121 to the first silver nanowire layer 111 may be changed according to an applied external force 141 or the like. Specifically, the frictional force between the first cellulose nanofiber layer 112 and the second silver nanowire layer 121 increases in proportion to the applied external force 141, so that the first cellulose nanofiber layer 112 2 The silver nanowire layer 121 has a relatively stronger polarity.

As shown in FIG. 8, the electric charge or current flows through the connection part 130 until the electrical equilibrium state in the first film 110 is reached, and finally, the first silver nanowire of the first film 110 The layer 111 is charged as an anode, and the first cellulose nanofiber layer 112 is in equilibrium while being charged as a cathode.

As shown in FIG. 9, when the first film 110 and the second film 120 are relatively approached again due to the external force 143 acting (that is, the first cellulose nanofiber layer 112 and the second film) 2 When the silver nanowire layers 121 are relatively close to each other), since the first cellulose nanofiber layer 112 is charged as a negative electrode, negative charges of the second silver nanowire layer 121 are emitted to the outside. . The negative charge emitted to the outside is transferred to the connection part 130, and is transferred to the first silver nanowire layer 111 through the connection part 130. Accordingly, the polarity of the first silver nanowire layer 111 is relatively weakened, and the polarity of the second silver nanowire layer 121 is relatively strong.

As a result of continuous approach, all or part of the first film 110 may come into contact with all or part of the second film 120. In this case, as shown in FIG. 6, the second silver nanowire layer 121 rubbed against the first cellulose nanofiber layer 112 is charged as an anode, and the first silver nanowire layer 111 is substantially neutral. Is displayed.

The first film 110 and the second film 120 may be separated from each other depending on the surrounding environment 142, and by such separation, as shown in FIG. 7, the first silver nanowire layer 111 The second silver nanowire layer 121 is transferred, and current flows from the second silver nanowire layer 121 to the first silver nanowire layer 111 on the contrary.

The operation of the triboelectric energy harvester 100 described in detail with reference to FIGS. 6 to 9 may be sequentially and continuously repeated, and accordingly, the current (charge) may repeatedly flow in at least one direction to the connection unit 130. do.

Hereinafter, an embodiment of a process of manufacturing at least one of the first film 110 and the second film 120 of the triboelectric energy harvester 100 will be described with reference to FIGS. 10 to 12.

10 is a first diagram illustrating a manufacturing process of each film of a triboelectric energy harvester, and FIG. 11 is a second diagram illustrating a manufacturing process of each film of a triboelectric energy harvester. 12 is a third diagram for explaining the manufacturing process of each film of the triboelectric energy harvester.

For example, the first film 110 of the triboelectric energy harvester 100 described above may be manufactured through a process as shown in FIGS. 10 to 12.

Specifically, as shown in FIG. 10, first, a predetermined filter film 190 is provided. The filtering film 190 refers to a film in which cellulose nanofibers and silver nanowires are seated, but other components (eg, water, etc.) other than cellulose nanofibers and silver nanowires are filtered.

When the filter film 190 is prepared, a silver solution 191 obtained by dissolving silver (eg, silver ions) is provided to the filter film 190. The silver solution 191 may be obtained by mixing, for example, a silver salt, a polyol solvent, and a precursor solution. Provision of the silver solution 191 is, for example, immersing the filter film 190 in the silver solution 191, spraying the silver solution 191, or the silver solution 191 on the filter film 190 A method such as flowing through and permeating may be used.

The concentration of the silver nanowires dissolved in the silver solution 191 may be determined according to the required size of the electrical output of the first film 110. For example, in the case of relatively increasing the size of the current output from the first film 110, a silver solution 191 having a relatively high concentration of silver nanowires is transmitted through the filter film 190, and vice versa. When the size of the current output from the first film 110 is to be relatively small, a silver solution 191 having a relatively low concentration of silver nanowires is transmitted through the filter film 190.

As the silver solution 191 is provided, silver nanowires remain on one surface of the filter film 190, and all or most of the materials other than the silver nanowires pass through the filter film 190. Accordingly, a filtration film 190 in which the silver nanowire layer 111 is formed on at least one surface may be obtained.

As shown in FIG. 11, a cellulose solution 192 may be sequentially provided to the filter film 190 on which the silver nanowire layer 111 obtained by the above-described method is formed. The cellulose solution 192 may include, for example, a cellulose nanofiber suspension. The cellulose solution 192 is also provided by immersing the filtration film 190 on which the silver nanowire layer 111 is formed in the cellulose solution 192, spraying the cellulose solution 192, or the cellulose solution on the filtration film 190 It may be carried out using a method of flowing 192 and the like. Accordingly, the cellulose solution 192 is formed by being dispersed in the filtration film 190 on which the silver nanowire layer 111 is formed. In this case, the cellulose solution 192 may be formed by being dispersed in the filter film 190 in a plurality of times. As the number of dispersions of the cellulose solution 192 increases, the magnitude of the current output from the first film 110 increases.

When the cellulose solution 192 is added, the cellulose nanofibers are attached on the silver nanowire layer 111 to form the cellulose nanofiber layer 112, and all or most of the materials other than the cellulose nanofibers are silver nanowire layers. (111) and the filter film 190 is transmitted through. Accordingly, a filtration film 190 in which a cellulose nanofiber layer 111 is further formed on at least one surface may be obtained.

After the silver nanowire layer 111 and the cellulose nanofiber layer 112 are sequentially formed, the filtration film 190 may be separated and separated from the silver nanowire layer 111. Accordingly, a first film 110 in which the silver nanowire layer 111 and the cellulose nanofiber layer 112 are sequentially stacked is obtained and manufactured. The second film 120 may also be manufactured and obtained through the same method.

As described above, when the first film 110 and the second film 120 are each manufactured, the two silver nanowire layers 111 and 121 are electrically connected to each other by the connection part 130. In addition, at the same time, following or preceding this, the first film 110 and the second film 120 are approximately aligned side by side as described above. Accordingly, the triboelectric charging energy harvester 100 including the first film 110 and the second film 120 is obtained.

Depending on the embodiment, the above-described method may be used to manufacture both the first film 110 and the second film 120 of the triboelectric energy harvester 100, or the first film 110 and the first film. 2 It may be used to manufacture only one of the films 120. In this case, the other one of the first film 110 and the second film 120 may be manufactured through a conventionally known method different from that described above.

In addition, the above-described triboelectric energy harvester 100 may be used in various fields.

Specifically, the triboelectric energy harvester 100 has availability. Accordingly, the triboelectric energy harvester 100 may be used to manufacture an electric device that can be dissolved in water.

In addition, the triboelectric energy harvester 100 may be used as an electronic paper (e-paper), or may be used as an electronic sensor for detecting folding and/or humidity.

Hereinafter, an embodiment of an electronic paper using the triboelectric energy harvester described above will be described with reference to FIGS. 13 and 14.

13 is a conceptual diagram of an embodiment of an electronic paper, and FIG. 14 is a diagram for explaining an embodiment of an operation of the electronic paper.

As shown in FIG. 13, the electronic paper 200 may include a first film 210 and a second film 220 in an embodiment, and also the first film 210 and the second film ( It may further include a connection unit 230 for electrically connecting 220.

As described above, the first film 210 includes a first silver nanowire layer 211 and a first cellulose nanofiber layer 212, and the second film 220 includes a second silver nanowire layer ( 221) and a second cellulose nanofiber layer 222. Each of the first film 210 and the second film 220 has a laminated structure as shown in FIG. 14. That is, the first silver nanowire layer 211 and the first cellulose nanofiber layer 212 of the first film 210 are formed by stacking layers, and similarly, the second silver nanowire layer 221 of the second film 220 ) And the second cellulose nanofiber layer 222 are also formed by stacking layers. In addition, as previously described, the first film 210 and the second film 220 are aligned substantially in parallel, but the first cellulose nanofiber layer 212 and the second nanowire layer 221 may face each other. So that they are aligned in a predetermined direction.

Hereinafter, the operation of the electronic paper 200 implemented as described above will be described in more detail.

As shown in FIG. 14, a pressing body 99 (for example, at least one finger) on one surface of the electronic paper 200 (for example, one surface exposed to the outside of the first silver nanowire layer 211) When pressure is applied by the action of the terminal, nails, palms, writing instruments such as pencils or ballpoint pens, smart pens, stylus pens and/or erasers, etc.), a portion 290 of the first film 210 to which pressure is applied ) Is pushed in the direction of the second film 220 and is depressed. Accordingly, a portion 290 of the first film 210 comes into contact with the second film 220. In other words, the first cellulose nanofiber layer 212 comes into contact with the second silver nanowire layer 221. As a result, as described above, friction occurs between the first cellulose nanofiber layer 212 and the second silver nanowire layer 221, and according to the friction, the first cellulose nanofiber layer 212 and the second silver nanowire layer 212 Each of the wire layers 221 is charged. Thereafter, when the pressure is removed, the first cellulose nanofiber layer 212 and the second silver nanowire layer 221 may be separated from each other due to elastic force, etc., and current through the connection part 230 as shown in FIG. 7 Is created. As the current is generated, the electronic ink or the like in the electronic paper 200 receives an electrical stimulation, and the electronic ink or the like is rearranged in response to the electrical stimulation. Through this method, the electronic paper 200 may display a predetermined image (eg, symbols, characters, figures, and/or colors, etc.) or may prevent the displayed image from being displayed any more.

14 illustrates an example in which the member 99 is pressed against the first silver nanowire layer 211, but the pressing direction is not limited thereto. For example, even when the pressing body 99 is pressed on the second cellulose nanofiber layer 222, the same or approximate effect as described above can be obtained.

In addition, although only the first film 210 and the second film 220 are shown in FIG. 14, in addition, the outer surface of the first film 210 (that is, the first silver nanowire layer 211 exposed to the outside) Side) and the outer surface of the second film 220 (that is, one side of the second cellulose nanofiber layer 222 exposed to the outside) to protect the first film 210 and the second film 220 It is also possible to further form a film or the like.

Hereinafter, various embodiments of an electronic sensor using a triboelectric energy harvester will be described with reference to FIGS. 15 and 17.

15 is a conceptual diagram of an electronic sensor according to an embodiment.

As shown in FIG. 15, in an embodiment, the electronic sensor 300 includes a first film 310 including a first silver nanowire layer 311 and a first cellulose nanofiber layer 312, and 2 may include a second film 320 including a silver nanowire layer 321 and a second cellulose nanofiber layer 322.

The electronic sensor 300 connects a connection 330 electrically connecting the first silver nanowire layer 311 of the first film 310 and the second silver nanowire layer 321 of the second film 320 It may further include, and may further include a signal detection unit 335 for sensing an electrical signal transmitted from the connection unit 330.

Referring to FIG. 16, as described above, the first silver nanowire layer 311 and the first cellulose nanofiber layer 312 of the first film 310 are stacked and formed, and the second film ( The second silver nanowire layer 321 and the second cellulose nanofiber layer 322 of 320 are also stacked and formed. In addition, the first film 310 and the second film 320 are each aligned substantially parallel to each other, but the first cellulose nanofiber layer 312 and the second silver nanowire layer 321 may rub against each other due to pressure, etc. So they are aligned.

The signal detection unit 335 may be installed on the connection unit 330. The signal detection unit 335 is transferred from the first film 310 to the second film 320 through the connection part 330 and/or the second film 320 through the connection part 330. It is provided to detect an electrical signal transmitted to 310). In addition, the signal detection unit 335 may be provided to further perform a predetermined operation in response to the detected electrical signal according to an exemplary embodiment. For example, the signal detection unit 335 may output a corresponding electrical signal in response to detection of an electrical signal and transmit it to another external device (for example, a processor, etc.), or a predetermined control corresponding to the detected electrical signal. The signal may be directly generated and transmitted to an external controlled device (that is, the signal detection unit 335 may perform the function of the control unit), and the magnitude of the electric signal and/or the number of occurrences of the electric signal may be measured. You can also count. In addition, the signal detector 335 may be designed to perform various operations that may be considered by a designer.

Hereinafter, various embodiments of the electronic sensor 300 and the operation thereof will be described in more detail.

16 is a diagram illustrating an example of an operation of an electronic sensor that detects folding.

As shown in FIG. 16, the electronic sensor 300 may include a folding detection sensor 340 for detecting folding.

Specifically, when folding occurs in a portion 401 due to an external force or the like in the folding detection sensor 340, the sheet resistance of the corresponding portion of each film 350 and 360 of the folding detection sensor 340 is relatively changed. do. The more the folding is repeated, the more the sheet resistance changes correspondingly. When the surface resistance is changed, the first silver nanowire according to the friction between the first cellulose nanofiber layer 352 of the first film 350 and the second silver nanowire layer 361 of the second film 360 The magnitude of the current flowing between the layer 351 and the second silver nanowire layer 361 also changes. The signal detector 335 may sense a current flowing between the first silver nanowire layer 351 and the second silver nanowire layer 361 and measure the magnitude of the current. The number of folds of the fold detection sensor 340 may be measured according to the measurement result of the signal detection unit 335.

In addition, the electronic sensor 300 described above may be used as a humidity sensor. Cellulose nanofibers have a property of adsorbing moisture well, and the electronic sensor 300 using the triboelectric energy harvester 100 described above based on this property may be used as the humidity sensor 370.

For example, when moisture is increased in the atmosphere, more moisture may be adsorbed to the cellulose nanofibers, and such an increase in moisture is the first cellulose nanofiber layer 312 and the second film of the first film 310 The size of the polarity when each of the second silver nanowire layers 321 of 320 is charged is changed. Accordingly, the magnitude of the current transmitted between the first silver nanowire layer 311 and the second silver nanowire layer 321 also changes with an increase in moisture. The signal detector 335 may detect such a change in current magnitude. The signal detection unit 335 or another device (for example, a processor) electrically connected to the signal detection unit 335 calculates or detects humidity corresponding to such a change in current magnitude. This makes it possible to measure the humidity in the air.

The above-described triboelectric energy harvester, the method of manufacturing the triboelectric energy harvester, the operation method of the triboelectric energy harvester, and the electronic paper and electronic sensor using the triboelectric energy harvester include books, industrial robots, mechanical devices and equipment, and electronic devices. It can be used in various fields such as devices, clothing, vehicles, workpieces, Internet of Things (IoT), various other electronic/mechanical devices, and/or electronic components or materials that can be employed therein.

Here, the electronic device may include an industrial electronic device and/or an electronic device used for home use, and the electronic device used for home may include, for example, a home appliance, a display device, a set-top box, a desktop computer, It may include at least one of a laptop computer, a sound reproducing device, an automated teller machine (ATM), or various devices capable of inputting and modifying other codes. Here, the home appliance may include a refrigerator, a microwave, an electric oven, a dishwasher, a washing machine, an induction heating device, a heating pot, a vacuum cleaner, a robot cleaner, and/or various electronic devices used in the home. In addition, display devices include, for example, digital televisions, monitor devices, smart phones, tablet PCs, electronic books, wearable devices (smart watches, head mounted displays (HMD, Head Mounted Display), etc.), navigation devices, portable game machines, A personal digital assistant (PDA), an electronic blackboard, an electronic billboard, and/or other various devices capable of displaying a predetermined image may be included.

Various embodiments of an ideal triboelectric energy harvester, a method of manufacturing the triboelectric energy harvester, a method of operating the triboelectric energy harvester, and an electronic paper and an electronic sensor using the triboelectric energy harvester have been described, but the triboelectric energy harvester, The method for manufacturing the triboelectric energy harvester, the method for operating the triboelectric energy harvester, and the electronic paper and electronic sensor using the triboelectric energy harvester are not limited to the above-described embodiments. Various devices or methods that can be implemented by modifying and modifying based on the above-described embodiment by a person of ordinary skill in the relevant technical field also include the above-described triboelectric energy harvester, the method of manufacturing the triboelectric energy harvester, and the triboelectric energy harvester. It may be an example of an operation method, an electronic paper and an electronic sensor using the triboelectric energy harvester. For example, the described techniques are performed in a different order from the described method, and/or components such as structures, devices, circuits, etc. described are combined or combined in a form different from the described method, or other components or equivalents Even if it is replaced or replaced by the above-described triboelectric charge energy harvester, the method of manufacturing the triboelectric charge energy harvester, the operation method of the triboelectric charge energy harvester, an electronic paper and an electronic sensor using the triboelectric charge energy harvester may be an embodiment. .

1: triboelectric energy harvester 10: first film
11: first electrode material 12: first charged material
20: second film 21: second electrode material
22: second charged material 30: connection portion
100: triboelectric energy harvester 110: first film
111: first silver nanowire layer
112: first cellulose nanofiber layer 120: second film
121: second silver nanowire layer
122: second cellulose nanofiber layer 130: connection portion
190: filtration film 191: cellulose solution
192: silver solution 200: electronic paper
300: electronic sensor

Claims (7)

A first film including a first silver nanowire layer and a first cellulose nanofiber layer;
A second film including a second silver nanowire layer; And
It includes a connection part electrically connecting the first film and the second film,
When the first cellulose nanofiber layer approaches and rubs against the second silver nanowire layer, in response to this, the first cellulose nanofiber layer is charged to a negative electrode, and the second silver nanowire layer is charged to a positive electrode,
The first film,
Filtering the silver nanowire solution through a filter film to obtain a filter film having a silver nanowire layer formed thereon;
Filtering the cellulose solution through the filter film on which the silver nanowire layer is formed to obtain a filter film on which the cellulose nanofiber layer is further formed; And
It is prepared through the step of obtaining the first film by removing the filter film from the filter film in which the cellulose nanofiber layer is further formed,
The strength of the current flowing through the connection portion corresponds to the concentration of the silver nanowires in the silver nanowire solution or the triboelectric energy harvester corresponding to at least one of a dispersion degree and a pressure of the cellulose nanofibers. The method of claim 1,
The connection part electrically connects the first silver nanowire layer and the second silver nanowire layer to each other,
One side of the first cellulose nanofiber layer of the first film is in contact with the first silver nanowire layer, and the other side of the first cellulose nanofiber layer of the first film is a first side of the second film. 2 points towards the nanowire layer,
When the first cellulose nanofiber layer is separated from the second silver nanowire layer, an electric current from the second silver nanowire layer to the first silver nanowire layer moves through the connection portion. The method of claim 2,
The current is a triboelectric energy harvester flowing to the first silver nanowire layer until the first cellulose nanofiber layer and the first silver nanowire layer are in equilibrium with each other. Obtaining a first film;
Obtaining a second film; And
Including; electrically connecting the first film and the second film and arranging them side by side with each other,
The step of obtaining the first film,
Filtering the first silver nanowire solution through a first filter film to obtain a filter film on which the first silver nanowire layer is formed;
Filtering the first cellulose solution through the filter film on which the first silver nanowire layer is formed to obtain a filter film on which the first cellulose nanofiber layer is further formed; And
A method of manufacturing a triboelectric energy harvester comprising: removing the first filtration film from the filtration film having the first cellulose nanofiber layer further formed thereon to obtain the first film. A first film including a first silver nanowire layer and a first cellulose nanofiber layer;
A second film including a second silver nanowire layer whose one side faces the first cellulose nanofiber layer; And
It includes a connection part electrically connecting the first film and the second film,
When the first cellulose nanofiber layer approaches and rubs against the second silver nanowire layer, in response to this, the first cellulose nanofiber layer is charged as a negative electrode, and the second silver nanowire layer is charged as a positive electrode,
When the first cellulose nanofiber layer is separated from the second silver nanowire layer, a current is generated from the second silver nanowire layer to the first silver nanowire layer,
The first film,
Filtering the silver nanowire solution through a filter film to obtain a filter film having a silver nanowire layer formed thereon;
Filtering the cellulose solution through the filter film on which the silver nanowire layer is formed to obtain a filter film on which the cellulose nanofiber layer is further formed; And
It is produced through the step of obtaining the first film by removing the filter film from the filter film further formed with the cellulose nanofiber layer,
The second film,
Electronic paper comprising a; a second cellulose nanofiber layer formed on the other side of the second silver nanowire layer facing the one side. The method of claim 5,
The connection part electrically connects the first silver nanowire layer and the second silver nanowire layer to each other,
One side of the first cellulose nanofiber layer of the first film is in contact with the first silver nanowire layer, and the other side of the first cellulose nanofiber layer of the first film is a first side of the second film. 2 E-paper facing the silver nanowire layer. The method of claim 5,
Electronic paper that displays an image or blocks image display according to a pressure of a pressurized body applied to at least one of the first film and the second film.

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