KR20170111430A - Triboelectric energy generator using wave - Google Patents

Abstract

A triboelectric generating device using waves is disclosed. A triboelectric generating device using waves is a buoy that is positioned on the sea surface and is capable of performing at least one of up-down motion and rotational motion due to waves, and generates triboelectricity based on the motion. And a triboelectric generator positioned below the sea level and connected to the buoy to generate triboelectricity due to the motion of the buoy.

Description

TRIBOELECTRIC ENERGY GENERATOR USING WAVE <br> <br> <br> Patents - stay tuned to the technology TRIBOELECTRIC ENERGY GENERATOR USING WAVE

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a triboelectricity generating apparatus, and more particularly, to a triboelectricity generating apparatus capable of generating triboelectricity even under sea level and sea level using waves.

Until now, the structure of wave power generation was very complicated and power generation system using turbine rotation by wave was used, so a large power plant was needed. This type of power generation system not only hurts natural landscapes but also has a problem that it can be developed only in areas where a certain level of power can be obtained. In addition, there is a problem that the construction of a power plant consumes a huge amount of resources and costs, and takes a long time to construct. In addition, there is a problem that power generation is difficult unless a difference between a wave and a tidal range is formed for a certain level of wave and tidal power generation.

In order to solve such a problem, power generation devices using buoys have been developed, and Korean Patent No. 10-1356465 discloses a " buoy type wave power generation device ". However, the buoy-type wave power generator has the problem of producing electrical energy using a mechanically complex structure.

Therefore, the inventor of the present invention has developed a new type of electricity generating apparatus that can generate electricity by using buoys at sea level but can generate electricity even at sea level.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a triboelectric generating apparatus that can generate electric power without using a turbine and is simple in structure and can generate electricity even under sea level and sea level.

A triboelectric generator using waves according to a first embodiment of the present invention includes: a buoy which is positioned on the sea surface and is capable of performing at least one of up-down movement and rotational movement due to waves, and generating triboelectricity based on the movement; And a triboelectric generator positioned below the sea surface and connected to the buoy to generate triboelectricity by being affected by motion of the buoy, wherein the buoy is disposed within the buoy and comprises a first main body; A first substrate fixed to a lower surface of the first main body; A first electrode disposed on the first substrate; First friction material layers disposed on the first electrode and having a plurality of protrusions extending in one direction at a surface of the first electrode; A second substrate disposed below the upper surface of the first main body; And a plurality of protrusions disposed on a lower surface of the second substrate so as to face and contact the first friction material layers and extend in the same direction as the extending direction of the first friction material layers, The strip includes second layers of friction material which, when the buoy moves, generate triboelectric forces while the second layers of friction material are in contact with and non-contact with the first layers of friction material.

The triboelectric generator associated with the buoy is the same in all embodiments and will be described only once at the back.

A triboelectric generator using waves according to a second embodiment of the present invention includes: a buoy which is positioned on the sea surface and is capable of performing at least one of up-down movement and rotation movement by waves, and generating triboelectricity based on the movement; And a triboelectric generator positioned below the sea surface and connected to the buoy to generate triboelectricity by being affected by motion of the buoy, wherein the buoy is disposed within the buoy and comprises a first main body; A first substrate fixed to a lower surface of the first main body; A first electrode disposed on the first substrate; First friction material layers disposed on the first electrode and having a plurality of protrusions extending in one direction at a surface of the first electrode; A second substrate disposed below the upper surface of the first main body; A second electrode disposed on a lower surface of the second substrate; And a plurality of first friction material layers disposed on the lower surface of the second electrode and disposed on the lower surface so as to be in contact with and non-contact with the first friction material layers and extending in the same direction as the extending direction of the first friction material layers Wherein the second friction material layers are in contact with and non-contact with the first friction material layers when the buoy is in motion, thereby generating triboelectricity.

A triboelectric generating apparatus using waves according to a third embodiment of the present invention includes: a buoy which is positioned on the sea surface and is capable of performing at least one of up-down motion and rotational motion due to waves, and generating triboelectricity based on the motion; And a triboelectric generator positioned under the sea level and connected to the buoy to generate triboelectricity under the influence of motion of the buoy, wherein the buoy includes: a first substrate fixed within the buoy; A plurality of first electrodes disposed on the first substrate; Wherein the first friction material layers are disposed on the first electrodes, wherein the first friction material layers comprise a first friction material layer having a first friction material layer and a second friction material layer, Material layers; A second substrate disposed on the second layer of friction material; A second electrode disposed on a lower surface of the second substrate; And a plurality of first friction material layers disposed on the lower surface of the second electrode and disposed on the lower surface so as to be in contact with and non-contact with the first friction material layers and extending in the same direction as the extending direction of the first friction material layers Wherein the second friction material layers are in contact with and non-contact with the first friction material layers when the buoy is in motion, thereby generating triboelectricity.

The material of the second layer of friction material is preferably selected such that the charging property of the second layer of friction material on the triboelectric series is located between the charging properties of the first layers of friction material.

A triboelectric generator using waves according to a fourth exemplary embodiment of the present invention includes: a buoy which is positioned on the sea surface and is capable of performing at least one of up-down movement and rotational movement due to waves, and generating triboelectricity based on the movement; And a triboelectric generator positioned below the sea surface and connected to the buoy to generate triboelectricity by being influenced by motion of the buoy, wherein the buoy is fixed inside the buoy, A first substrate; A plurality of first electrodes arranged to surround the central axis of the first substrate on the first substrate and spaced apart from each other along the rotation direction of the central axis; First friction material layers disposed on the first electrodes, respectively; A second substrate having the rotation axis passing through a center of the second substrate and connected to the second substrate and rotated together with the rotation axis; A first substrate disposed on the lower surface of the second substrate and disposed to surround the central axis of the second substrate and spaced apart from one another in the direction of rotation of the central axis and contacting and noncontact with the first layers of friction material, 2 friction material layers; And a weight placed on the upper surface of the second substrate in a state spaced apart from the center of the second substrate. When the buoy is moved, the second substrate rotates by the weight of the weight, Material layers are contactable and noncontact with the first layers of friction material.

A triboelectric generator using waves according to a fifth embodiment of the present invention includes: a buoy which is positioned on the sea surface and is capable of performing at least one of up-down movement and rotation movement by waves, and generating triboelectricity based on the movement; And a triboelectric generator positioned below the sea surface and connected to the buoy to generate triboelectricity by being influenced by motion of the buoy, wherein the buoy is fixed inside the buoy, A first substrate; A plurality of first electrodes arranged to surround the central axis of the first substrate on the first substrate and spaced apart from each other along the rotation direction of the central axis; First friction material layers disposed on the first electrodes, respectively; A second substrate having the rotation axis passing through a center of the second substrate and connected to the second substrate and rotated together with the rotation axis; A second electrode disposed on a lower surface of the second substrate; One or more second friction material layers disposed on the bottom surface of the second electrode and disposed to surround the central axis of the second substrate and spaced apart from one another in the rotational direction of the central axis and contactable and non- ; And a weight placed on the upper surface of the second substrate in a state spaced apart from the center of the second substrate. When the buoy is moved, the second substrate rotates by the weight of the weight, Material layers are contactable and noncontact with the first layers of friction material.

A triboelectric generating apparatus using waves according to a sixth embodiment of the present invention includes: a buoy which is positioned on the sea surface and is capable of performing at least one of up-down movement and rotational movement due to waves, and generating triboelectricity based on the movement; And a triboelectric generator positioned below the sea surface and connected to the buoy to generate triboelectricity by being influenced by motion of the buoy, wherein the buoy is fixed inside the buoy, A first substrate; A plurality of first electrodes arranged to surround the central axis of the first substrate on the first substrate and spaced apart from each other along the rotation direction of the central axis; The first friction material layers being disposed on the first electrodes and each of the first friction material layers being made of a material having a charging property different from the charging property of the adjacent first friction material layer, ; A second substrate having the rotation axis passing through a center of the second substrate and connected to the second substrate and rotated together with the rotation axis; A first substrate disposed on the lower surface of the second substrate and disposed to surround the central axis of the second substrate and spaced apart from one another in the direction of rotation of the central axis and contacting and noncontact with the first layers of friction material, 2 friction material layers; And a weight placed on the upper surface of the second substrate in a state spaced apart from the center of the second substrate. When the buoy is moved, the second substrate rotates by the weight of the weight, Material layers are contactable and noncontact with the first layers of friction material.

Preferably, the first friction material layers are configured such that materials having two different charging characteristics are alternately arranged, and the material of the second friction material layer is selected from the group consisting of a charge of the second friction material layer on the triboelectric series Properties are selected to be located between the charging properties of the first friction material layers.

A triboelectric generating apparatus using waves according to a seventh embodiment of the present invention includes: a buoy which is positioned on the sea surface and is capable of performing at least one of up-down movement and rotational movement due to waves, and generating triboelectricity based on the movement; And a triboelectric generator positioned below the sea surface and connected to the buoy to generate triboelectricity by being influenced by motion of the buoy, wherein the buoy is fixed inside the buoy, A first substrate; A plurality of first electrodes arranged to surround the central axis of the first substrate on the first substrate and spaced apart from each other along the rotation direction of the central axis; The first friction material layers being disposed on the first electrodes and each of the first friction material layers being made of a material having a charging property different from the charging property of the adjacent first friction material layer, ; A second substrate having the rotation axis passing through a center of the second substrate and connected to the second substrate and rotated together with the rotation axis; A second electrode disposed on a lower surface of the second substrate; One or more second friction material layers disposed on the bottom surface of the second electrode and disposed to surround the central axis of the second substrate and spaced apart from one another in the rotational direction of the central axis and contactable and non- ; And a weight placed on the upper surface of the second substrate in a state spaced apart from the center of the second substrate. When the buoy is moved, the second substrate rotates by the weight of the weight, Material layers are contactable and noncontact with the first layers of friction material.

Preferably, the first friction material layers are configured such that materials having two different charging characteristics are alternately arranged, and the material of the second friction material layer is selected from the group consisting of a charge of the second friction material layer on the triboelectric series Properties are selected to be located between the charging properties of the first friction material layers.

The frictional electricity generating unit includes: a second body having an internal space formed therein; A third substrate fixed to a lower surface of the second main body; A third electrode layer disposed on the third substrate; A third friction material layer disposed on the third electrode layer; A fourth friction material layer capable of contacting and non-contacting with the third friction material layer and serving as an electrode; A fourth substrate disposed on the fourth friction material layer; And an engaging portion coupled to an upper surface of the fourth substrate, wherein the engaging portion causes the fourth substrate to move up and down by the motion of the buoy, so that the fourth friction material layer contacts the third friction material layer Contact and noncontact to generate triboelectricity.

The frictional electricity generating unit includes: a second body having an internal space formed therein; A third substrate fixed to a lower surface of the second main body; A third electrode layer disposed on the third substrate; A third friction material layer disposed on the third electrode layer; A fourth friction material layer capable of contacting and non-contacting the third friction material layer; A fourth electrode layer disposed on the fourth friction material layer; A fourth substrate disposed on the fourth electrode layer; And an engaging portion coupled to an upper surface of the fourth substrate, wherein the engaging portion causes the fourth substrate to move up and down by the motion of the buoy, so that the fourth friction material layer contacts the third friction material layer Contact and noncontact to generate triboelectricity.

The present invention as described above can generate electric energy eco-friendly using waves, and generate electric energy simultaneously under sea level and sea level.

The present invention has a simple structure and is easy to manufacture and can be manufactured at low cost.

1 is a conceptual diagram for explaining a triboelectricity generating apparatus using waves according to an embodiment of the present invention.
2 is a view of a buoy of a triboelectric generator using waves according to a first embodiment of the present invention.
3 is a view of a buoy of a triboelectric generator using waves according to a second embodiment of the present invention.
4 is a view of a buoy of a triboelectric generator using waves according to a third embodiment of the present invention.
5 is a view of a buoy of a triboelectric generator using waves according to a further embodiment of the present invention.
6 is a view of a buoy of a triboelectricity generating apparatus using waves according to a fourth embodiment of the present invention.
7 is a view of a buoy of a triboelectric generator using waves according to a fifth embodiment of the present invention.
8 is a view of a buoy of a triboelectric generator using waves according to a sixth embodiment of the present invention.
FIG. 9 is a view of a buoy of a triboelectric generator using waves according to a seventh embodiment of the present invention.
10 is a view for explaining a triboelectric generator according to an embodiment of the present invention.
11 is a graph illustrating a voltage measured in a triboelectric generator according to an embodiment of the present invention.
12 is a graph of voltage and current measured when a portion of the fourth friction material layer of the triboelectric generating portion is in contact with and does not contact a portion of the third friction material layer.

While the invention is susceptible to various modifications and alternative forms, specific embodiments thereof are shown by way of example in the drawings and will herein be described in detail. It should be understood, however, that the invention is not intended to be limited to the particular embodiments, but includes all modifications, equivalents, and alternatives falling within the spirit and scope of the invention.

Hereinafter, a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings. Wherein like reference numerals refer to like elements throughout.

1 is a conceptual diagram for explaining a triboelectricity generating apparatus using waves according to an embodiment of the present invention.

Referring to FIG. 1, a triboelectric generator 1000 using waves according to an embodiment of the present invention may include a buoy 100 and a triboelectric generator 200.

The buoy 100 is located on the sea surface and is capable of at least one of up-and-down motion and rotational motion due to waves, and can generate triboelectric motions by up-down motion and rotational motion. The triboelectricity generator 200 is a portion capable of generating additional triboelectricity according to the motion of the buoy. Hereinafter, the buoy 100 and the triboelectric generator 200 will be described in detail for each structure.

Hereinafter, the structure of the buoy table 100 will be described in order from the first embodiment to the fifth embodiment. The structure of the triboelectric generator 200 will be further described with reference to the embodiments.

2 is a view of a buoy of a triboelectric generator using waves according to a first embodiment of the present invention.

A tally of a triboelectricity generating apparatus using waves according to the first embodiment of the present invention includes a first body 10; A first substrate (11); A first electrode (12); First friction material layers (13); A second substrate (21); And second friction material layers (23).

The first body 10 is disposed inside the buoy 100 and may be fixed inside the buoy. The first body 10 has a space formed therein as shown in FIG. 2, and a structure for generating electrical energy by friction is formed in the space. The first body is preferably made of an insulating material, but is not limited thereto.

The first substrate 11 is fixed to the lower surface of the first main body. The material of the first substrate can be any material that can be used as a substrate, and there is no particular limitation thereto.

The first electrode 12 may be disposed on the first substrate and the material of the first electrode may be any material that can be used as the electrode material. Although the first electrode 12 is shown as a single layer in FIG. 2, it may be disposed on the substrate in some cases divided into a plurality of electrodes. In this case, the first friction material layers 13 may be disposed, respectively.

The first friction material layers 13 are a plurality of protrusions disposed on the first electrode 12 and extending in one direction at the surface of the first electrode. The plurality of protrusions are spaced apart from each other and extend in a rod-like shape in one direction. The plurality of protrusions corresponding to the first friction material layers 13 are portions where the second friction material layers 23 contact and are not contacted with each other as described later, do. The adjustment of the height can be variously controlled by adjusting the height of the substrate.

A second substrate 21 is disposed below the upper surface of the first main body as shown in Fig. And the second substrate is not fixed to the upper surface of the inside of the first body. The size of the second substrate 21 is preferably smaller than that of the first substrate 11 so that the first friction material layers 13 and the second friction material layers 23 contact and are in contact with each other May be variously generated in a sliding form or a pushing form. The material of the second substrate can be any material that can be used as a substrate, and there is no particular limitation thereto.

The second friction material layers 23 are disposed on the lower surface of the second substrate 21 and disposed so as to be in contact with and non-contact with the first friction material layers 13. These second layers of friction material 23 are a plurality of protrusions extending in one direction at the surface of the second substrate. The plurality of protrusions are spaced apart from each other and extended in a bar shape in the same direction as the extending direction of the first friction material layers.

It is preferable that the first friction material layers 13 and the second friction material layers 23 are made of a material having charging characteristics different from each other. The fact that the charging characteristics are different from each other means that the charging characteristics are arranged at different positions on the triboelectric series, and the larger the difference in the charging characteristics, the larger the triboelectricity can be generated.

Meanwhile, in the first embodiment of the present invention, the second friction material layers 23 themselves are made of a conductive material because they also function as electrodes.

According to the first embodiment of the present invention, by the structure inside the buoy described above, when the buoy moves, the first friction material layers and the second friction material layers repeatedly contact and non-contact each other to generate triboelectricity. In this case, friction between the first friction material layers and the second friction material layers may be generated by mixing the sliding method or the pushing method or the like.

And may include a lead portion and an energy storage portion that are electrically connected to the electrode material to collect the triboelectricity generated by the friction between the friction material layers. Although not specifically shown in the figure, the first lead portion is electrically connected to the first electrode, and the second lead portion is electrically connected to the second electrode. In addition, the energy storage unit may be connected to the lead line, and devices capable of using or storing electricity such as a storage battery and an electronic device may be used as the energy storage unit. A rectifier diode (not shown) may be connected between the lead portion and the energy storage portion. A load may be connected to the drawer, thereby directly lighting the bulb. On the other hand, the diode serves as a rectifying diode to allow a current to flow only in one direction, thereby preventing current from flowing in reverse and discharging the battery or the like.

3 is a view of a buoy of a triboelectric generator using waves according to a second embodiment of the present invention.

A tally of a triboelectricity generating apparatus using waves according to a second embodiment of the present invention includes a first body 10; A first substrate (11); A first electrode (12); First friction material layers (13); A second substrate (21); A second electrode (22); And second friction material layers (23).

3 is the same as that of FIG. 2 except that the embodiment shown in FIG. 2 and the second electrode are separately provided. Therefore, Is omitted.

In the embodiment of FIG. 3, the second friction material layers 23 need not necessarily be a conductive material, and the second lead line is also connected to the second electrode, since the second electrode is separately provided as the electrode material.

4 is a view of a buoy of a triboelectric generator using waves according to a third embodiment of the present invention.

A tally of a triboelectricity generating apparatus using waves according to a third embodiment of the present invention includes a first body 10; A first substrate (11); A first electrode (12); First friction material layers (13); A second substrate (21); A second electrode (22); And second friction material layers (23).

3 is the same as that of the embodiment shown in FIG. 3 except for the difference of the first friction material layers. Therefore, the repetitive description of the same configuration is the same as that of FIG. It will be omitted.

In the embodiment of Fig. 4, the first friction material layers 13 are repeatedly arranged in one direction in combination of protrusions 13 and 13 'having two different rows and having different triboelectrification characteristics. In the embodiment of FIG. 4, the projections 13 and 13 'of the first friction material layers are repeatedly arranged side by side in the same direction, and the projections 23 of the second friction material layers are contacted or non- Or slidingly generates triboelectricity continuously. In this case also, the charging property of the second friction material layer 23 must be different from the charging property of the first friction material layers 13, 13 '. The charging property means that the charging property is arranged at different positions on the triboelectric series and preferably the material of the second friction material layer 23 is triboelectric material of the material of the first friction material layers 13 and 13 ' It is preferable to use a material positioned between the positions on the series.

5 is a view of a buoy of a triboelectric generator using waves according to a further embodiment of the present invention. 6 is a view of a buoy of a triboelectricity generating apparatus using waves according to a fourth embodiment of the present invention.

A buoy of an apparatus for generating triboelectricity using waves according to a fourth embodiment of the present invention is a buoy of a triboelectric generating apparatus using waves, which is located on the sea surface and is capable of performing at least one of up-down motion and rotational motion by waves, buoy; And a triboelectric generator positioned below the sea level and connected to the buoy to generate a triboelectricity under the influence of the motion of the buoy, wherein the buoy is fixed in the buoy and the rotation axis is arranged to penetrate the center A first substrate; A plurality of first electrodes arranged to surround the central axis of the first substrate on the first substrate and spaced apart from each other along the rotation direction of the central axis; First friction material layers disposed on the first electrodes, respectively; A second substrate having the rotation axis passing through a center of the second substrate and connected to the second substrate and rotated together with the rotation axis; A first substrate disposed on the lower surface of the second substrate and disposed to surround the central axis of the second substrate and spaced apart from one another in the direction of rotation of the central axis and contacting and noncontact with the first layers of friction material, 2 friction material layers; And a weight placed on the upper surface of the second substrate in a state spaced from the center of the second substrate.

5 and 6, the buoy 100 includes a first substrate 11, first electrodes 12, first friction material layers 13, a conductive second friction material layer 23, 2 substrate 21, a weight 60, and a rotating shaft 70. The substrate 21, the weight 60, The embodiments of Figures 5 and 6 correspond to embodiments in which the second electrode simultaneously serves as the second layer of friction material.

The first substrate 11 is fixed inside the buoy 100. For example, the first substrate 11 may be fixed by an engaging pin 80 coupled to the inside of the buoy 100, and the first substrate 310 may be formed in a disc shape. The plurality of first electrodes 12 are disposed on the first substrate 11. In this case, the first electrode may be disposed on the substrate in one plane instead of a plurality of the first electrodes.

When the first substrate 11 is a disk, the first electrodes 12 may be disposed on the first substrate 11 at a predetermined interval along the center of the disk. That is, the first electrodes 12 may be arranged radially with respect to the center of the first substrate 11. The first electrodes 12 may be fixed on the first substrate 11.

The first friction material layers 13 may be disposed on the first electrodes 12, respectively. The material constituting the first friction material layers 13 may be selected with reference to a known triboelectric series.

The second layer of friction material 23 is contactable and non-contactable with the layers of friction material 13. The second friction material layer 23 may be disposed on the second substrate 21, for example, the second substrate 21 may have a disc shape. In this embodiment, the second friction material layer is made of a conductive material, so that the second electrode serves also as a second electrode.

The second friction material layer 23 may be disposed on the second substrate 21 at a predetermined distance from the center of the second substrate 21, May have the same shape as one of the first electrodes 12 disposed on the substrate 11 and may be disposed on the second substrate 21 so as to correspond to the arrangement of the first electrodes .

The weight 60 may be disposed on the second substrate 23 away from the center of the second substrate 23. The weight 60 may be fixed to the second substrate 23.

The rotating shaft 70 can rotate the second substrate 23 and the rotating shaft 70 can rotate in the buoy 100. For example, the rotary shaft 70 may be rotated while the upper and lower ends of the rotary shaft 70 are respectively inserted into grooves formed in the buoy 100 so as to face each other.

The second substrate 21 fixed to the rotary shaft 70 rotates when the rotary shaft 70 rotates due to the weight of the weight 60 when the buoy 100 moves. By the rotation of the second substrate 21, the second layer of friction material 23 can come into contact with and come into contact with the first layers of friction material 13, and triboelectricity can be generated by such contact and noncontact.

7 is a view of a buoy of a triboelectric generator using waves according to a fifth embodiment of the present invention. 7 is the same as that shown in FIG. 6 except that the embodiment shown in FIG. 6 and the second electrode 22 are separately provided, so that the same constitution The repetitive description will be omitted.

In the embodiment of FIG. 7, the second friction material layers 23 need not necessarily be a conductive material, and the second lead line is also connected to the second electrode, since the second electrode is separately provided as an electrode material.

8 is a view of a buoy of a triboelectric generator using waves according to a sixth embodiment of the present invention. In the case of the sixth embodiment, repetitive description of the same configuration as that of the fourth embodiment described above will be omitted.

Referring to FIG. 8, a tally of a triboelectricity generating apparatus using waves according to a sixth embodiment of the present invention includes a first substrate 11; A plurality of first electrodes (12); First friction material layers (13) disposed on the first electrodes, respectively; A second substrate (21); Second outermost material layers (23); And a weight (60).

The sixth embodiment is characterized in that the first friction material layer disposed on the first electrodes is made of a material having a charging property different from the charging property of the adjacent first friction material layer. Whereby triboelectricity can be generated by contact by continuous rotation or the like.

On the other hand, it is preferable that the first friction material layers are made such that materials having two different charging characteristics are arranged alternately. In this case, when the first friction material layers are divided into the A and B zones and the second friction material layer is defined as the C zone as shown in FIG. 8, the charging characteristics of the materials of the A and B zones and the material of the C zone are different, Friction characteristics due to friction are generated because the charge characteristics are made of materials different from each other. The charging characteristics mean that they are disposed at different positions on the triboelectric series. Preferably, the material of the C zone is made of a material located between the positions on the triboelectric series of the materials of the A and B zones .

On the other hand, in the sixth embodiment, the second friction material layer must be a conductive material because the second friction material layer simultaneously serves as an electrode.

FIG. 9 is a view of a buoy of a triboelectric generator using waves according to a seventh embodiment of the present invention. The seventh embodiment is identical to the sixth embodiment except that the second electrode is separately provided.

In the embodiment of FIG. 9, the second friction material layers 23 need not necessarily be a conductive material, and the second lead line is also connected to the second electrode, since the second electrode is separately provided as the electrode material.

The generation of the triboelectricity in the buoy 100 in the triboelectric generator using the wave of the present invention has been described so far and the triboelectricity generated in the triboelectricity generator 200 connected to the buoy 100 will be described below I will explain the contents.

The triboelectric generator 200 is positioned below the sea surface and is connected to the buoy 100 and is capable of generating triboelectricity due to the motion of the buoy 100.

Referring to FIG. 10, the triboelectric generator 200 includes a second body 510, a third substrate 520, a third electrode layer 530, a third friction material Layer 540, a fourth layer of friction material 550, a fourth substrate 560, and an engaging portion 570.

A third substrate 520, a third electrode layer 530, a third friction material layer 540, a fourth friction material layer 550, and a fourth friction material layer 550 are formed in the second body 510, A fourth substrate 560 can be accommodated.

The third substrate 520 may be fixed within the second body 510 and the third substrate 520 may be fixed to the lower surface of the second body 510 using an adhesive. For example, the third substrate 520 may be made of a flexible material, for example, PET, but is not limited thereto.

The third electrode layer 530 may be disposed on the third substrate 520, and the third electrode layer 530 may be a thin film formed of copper. The conductive material may be used for the third electrode layer 530 and is not limited to copper.

The third layer of friction material 540 may be disposed on the third electrode layer 530 and the material of the third layer of friction material 540 may be selected with reference to a known triboelectric series . The third friction material layer 540 may be fixed on the third electrode layer 530. For example, one or more projections may be formed on the surface of the third friction material layer 540, and the output of the triboelectricity with the fourth friction material layer 550 may be improved by forming the projections.

The fourth layer of friction material 550 is capable of contacting and non-contacting the third layer of friction material 540 and may serve as an electrode. As an example, the fourth layer of friction material 550 may be made of a metallic material (e.g., copper, etc.) that is selected or conductive with reference to a triboelectric series known in the art.

A fourth substrate 560 may be disposed on the fourth friction material layer 550 and a fourth substrate 560 may be fixed on the fourth friction material layer 550. For example, the fourth substrate 560 may be made of a flexible material, for example, PET, but is not limited thereto.

The third substrate 520, the third electrode layer 530, the third friction material layer 540, the fourth friction material layer 550 and the fourth substrate 560 are formed through a roll to roll process .

The engaging portion 570 is coupled to the upper surface of the buoy 100 and the fourth substrate 560. For example, the connecting portion 570 may be formed of a string-shaped connecting means, and is preferably made of a material which is not corroded in seawater.

One end of the coupling portion 570 is coupled to the lower surface of the buoy 100 and the other end of the coupling portion 570 opposing the one end of the coupling portion 570 is coupled to the fourth surface of the fourth substrate 560, May be coupled to a first region that is spaced apart from the center of the substrate 560 by a predetermined distance. The engaging portion 570 pulls the fourth substrate 560 when the buoy 100 is lifted or rotated in the first direction so that the fourth friction material layer 550 and the third friction material layer 540 do not contact each other When the buoy 100 rotates in the direction opposite to the first direction, the engaging portion 570 releases the fourth substrate 560 without pulling the fourth substrate 560, The layer 550 and the third friction material layer 540 may be in contact with each other.

Since the engaging portion 570 is coupled to the first region of the upper surface of the fourth substrate 560, a portion of the fourth friction material layer 550 and a portion of the third friction material layer 540 are in contact with each other So as to make it possible to make it non-contact. For example, since the engaging portion 570 penetrates the second body 510 and is coupled with the buoy 100, the engaging portion 570 prevents the seawater from flowing into the second body 510 through the engaging portion 570 It is preferable that it is configured to pass through.

A lead line (not shown) may connect the third electrode layer 530 and the fourth friction material layer, and a load may be connected to the lead line. For example, a load can be a device that can use or store electricity such as a battery or an electronic device.

11 is a graph illustrating a voltage measured in a triboelectric generator according to an embodiment of the present invention. The left graph in FIG. 11 is a graph in which a change in voltage with time is measured when a portion of the fourth friction material layer 550 and a portion of the third friction material layer 540 are in quick contact or non-contact, The graph is a graph of changes in voltage over time when some areas of the fourth friction material layer 550 and some areas of the third friction material layer 540 are in slow or non-contact contact.

Referring to FIG. 11, when a portion of the fourth friction material layer 550 and a portion of the third friction material layer 540 are contacted or contacted quickly, the voltage is output in the form of AC . However, if a portion of the fourth layer of friction material 550 and a portion of the third layer of friction material 540 are in rapid contact or noncontact contact, the voltage may be in the form of a direct current (DC) 1 second, between about 0 second and about 8 seconds).

12 is a graph of voltage and current measured when a portion of the fourth friction material layer of the triboelectric generating portion is in contact with and does not contact a portion of the third friction material layer. 12 shows a state in which the fourth friction material layer and the third friction material layer are brought into contact with each other so that a distance between a partial region of the fourth friction material layer and a partial region of the third friction material layer is non- The result of measuring the voltage and current generated when the contact is made again.

Referring to FIG. 12, it can be seen that the time from when the voltage returns from 0 V to 0 V and the time from when the current returns from 0 A to 0 A again is about 2 seconds. Assuming that the height of the wave is about 1 m, it is expected that the voltage and current will be outputted in the triboelectric generating part for about 25 seconds.

While the invention has been shown and described with reference to certain preferred embodiments thereof, it will be understood by those skilled in the art that various changes and modifications may be made without departing from the spirit and scope of the invention as defined by the appended claims. Accordingly, the true scope of the present invention should be determined by the following claims.

Claims (26)

A buoy positioned on the sea surface and capable of at least one of up and down movement and rotation movement by waves and generating triboelectricity based on the movement; And
And a triboelectric generator positioned below the sea level and connected to the buoy to generate triboelectricity under the influence of motion of the buoy,
The buoy,
A first body disposed inside the buoy and having an internal space formed therein;
A first substrate fixed to a lower surface of the first main body;
A first electrode disposed on the first substrate;
First friction material layers disposed on the first electrode and having a plurality of protrusions extending in one direction at a surface of the first electrode;
A second substrate disposed below the upper surface of the first main body; And
And a plurality of protrusions arranged on the lower surface of the second substrate so as to be in contact with and non-contact with the first friction material layers and extending in the same direction as the extending direction of the first friction material layers, Comprises second friction material layers,
Wherein when the buoy is in motion, the second friction material layers are in contact with and non-contact with the first friction material layers to generate triboelectricity.
The method according to claim 1,
The triboelectric generating unit includes:
A second body having an inner space formed therein;
A third substrate fixed to a lower surface of the second main body;
A third electrode layer disposed on the third substrate;
A third friction material layer disposed on the third electrode layer;
A fourth friction material layer capable of contacting and non-contacting with the third friction material layer and serving as an electrode;
A fourth substrate disposed on the fourth friction material layer; And
And an engaging portion coupled to an upper surface of the fourth substrate and the buoy,
Wherein the engaging part moves the fourth substrate up and down by the motion of the buoy so that the fourth friction material layer is in contact with and does not contact the third friction material layer to generate triboelectricity.
The method according to claim 1,
The triboelectric generating unit includes:
A second body having an inner space formed therein;
A third substrate fixed to a lower surface of the second main body;
A third electrode layer disposed on the third substrate;
A third friction material layer disposed on the third electrode layer;
A fourth friction material layer capable of contacting and non-contacting the third friction material layer;
A fourth electrode layer disposed on the fourth friction material layer;
A fourth substrate disposed on the fourth electrode layer; And
And an engaging portion coupled to an upper surface of the fourth substrate and the buoy,
Wherein the engaging part moves the fourth substrate up and down by the motion of the buoy so that the fourth friction material layer is in contact with and does not contact the third friction material layer to generate triboelectricity.
A buoy positioned on the sea surface and capable of at least one of up and down movement and rotation movement by waves and generating triboelectricity based on the movement; And
And a triboelectric generator positioned below the sea level and connected to the buoy to generate triboelectricity under the influence of motion of the buoy,
The buoy,
A first body disposed inside the buoy and having an internal space formed therein;
A first substrate fixed to a lower surface of the first main body;
A first electrode disposed on the first substrate;
First friction material layers disposed on the first electrode and having a plurality of protrusions extending in one direction at a surface of the first electrode;
A second substrate disposed below the upper surface of the first main body;
A second electrode disposed on a lower surface of the second substrate; And
And a plurality of protrusions arranged on a lower surface of the second electrode and disposed on the lower surface so as to be able to contact and non-contact with the first friction material layers and extending in the same direction as the extending direction of the first friction material layers, A second friction material layer,
Wherein when the buoy is in motion, the second friction material layers are in contact with and non-contact with the first friction material layers to generate triboelectricity.
5. The method of claim 4,
The triboelectric generating unit includes:
A second body having an inner space formed therein;
A third substrate fixed to a lower surface of the second main body;
A third electrode layer disposed on the third substrate;
A third friction material layer disposed on the third electrode layer;
A fourth friction material layer capable of contacting and non-contacting with the third friction material layer and serving as an electrode;
A fourth substrate disposed on the fourth friction material layer; And
And an engaging portion coupled to an upper surface of the fourth substrate and the buoy,
Wherein the engaging part moves the fourth substrate up and down by the motion of the buoy so that the fourth friction material layer is in contact with and does not contact the third friction material layer to generate triboelectricity.
5. The method of claim 4,
The triboelectric generating unit includes:
A second body having an inner space formed therein;
A third substrate fixed to a lower surface of the second main body;
A third electrode layer disposed on the third substrate;
A third friction material layer disposed on the third electrode layer;
A fourth friction material layer capable of contacting and non-contacting the third friction material layer;
A fourth electrode layer disposed on the fourth friction material layer;
A fourth substrate disposed on the fourth electrode layer; And
And an engaging portion coupled to an upper surface of the fourth substrate and the buoy,
Wherein the engaging part moves the fourth substrate up and down by the motion of the buoy so that the fourth friction material layer is in contact with and does not contact the third friction material layer to generate triboelectricity.
A buoy positioned on the sea surface and capable of at least one of up and down movement and rotation movement by waves and generating triboelectricity based on the movement; And
And a triboelectric generator positioned below the sea level and connected to the buoy to generate triboelectricity under the influence of motion of the buoy,
The buoy,
A first board fixed within the buoy;
A plurality of first electrodes disposed on the first substrate;
Wherein the first friction material layers are disposed on the first electrodes, wherein the first friction material layers comprise a first friction material layer having a first friction material layer and a second friction material layer, Material layers;
A second substrate disposed on the second layer of friction material;
A second electrode disposed on a lower surface of the second substrate; And
And a plurality of protrusions arranged on a lower surface of the second electrode and disposed on the lower surface so as to be able to contact and non-contact with the first friction material layers and extending in the same direction as the extending direction of the first friction material layers, A second friction material layer,
Wherein when the buoy is in motion, the second friction material layers are in contact with and non-contact with the first friction material layers to generate triboelectricity.
8. The method of claim 7,
The triboelectric generating unit includes:
A second body having an inner space formed therein;
A third substrate fixed to a lower surface of the second main body;
A third electrode layer disposed on the third substrate;
A third friction material layer disposed on the third electrode layer;
A fourth friction material layer capable of contacting and non-contacting with the third friction material layer and serving as an electrode;
A fourth substrate disposed on the fourth friction material layer; And
And an engaging portion coupled to an upper surface of the fourth substrate and the buoy,
Wherein the engaging part moves the fourth substrate up and down by the motion of the buoy so that the fourth friction material layer is in contact with and does not contact the third friction material layer to generate triboelectricity.
8. The method of claim 7,
The triboelectric generating unit includes:
A second body having an inner space formed therein;
A third substrate fixed to a lower surface of the second main body;
A third electrode layer disposed on the third substrate;
A third friction material layer disposed on the third electrode layer;
A fourth friction material layer capable of contacting and non-contacting the third friction material layer;
A fourth electrode layer disposed on the fourth friction material layer;
A fourth substrate disposed on the fourth electrode layer; And
And an engaging portion coupled to an upper surface of the fourth substrate and the buoy,
Wherein the engaging part moves the fourth substrate up and down by the motion of the buoy so that the fourth friction material layer is in contact with and does not contact the third friction material layer to generate triboelectricity.
8. The method of claim 7,
Wherein the material of the second layer of friction material is selected such that the charging property of the second layer of friction material on the triboelectric series is positioned between the charging characteristics of the first layers of friction material.
A buoy positioned on the sea surface and capable of at least one of up and down movement and rotation movement by waves and generating triboelectricity based on the movement; And
And a triboelectric generator positioned below the sea level and connected to the buoy to generate triboelectricity under the influence of motion of the buoy,
The buoy,
A first board fixed inside the buoy and disposed so as to pass through the center of rotation;
A plurality of first electrodes arranged to surround the central axis of the first substrate on the first substrate and spaced apart from each other along the rotation direction of the central axis;
First friction material layers disposed on the first electrodes, respectively;
A second substrate having the rotation axis passing through a center of the second substrate and connected to the second substrate and rotated together with the rotation axis;
A first substrate disposed on the lower surface of the second substrate and disposed to surround the central axis of the second substrate and spaced apart from one another in the direction of rotation of the central axis and contacting and noncontact with the first layers of friction material, 2 friction material layers; And
And a weight placed on the upper surface of the second substrate in a state of being separated from the center of the second substrate,
Wherein the second friction material layers are capable of contacting and non-contacting the first friction material layers when the second substrate rotates due to the weight of the weight when the buoy moves.
12. The method of claim 11,
The triboelectric generating unit includes:
A second body having an inner space formed therein;
A third substrate fixed to a lower surface of the second main body;
A third electrode layer disposed on the third substrate;
A third friction material layer disposed on the third electrode layer;
A fourth friction material layer capable of contacting and non-contacting with the third friction material layer and serving as an electrode;
A fourth substrate disposed on the fourth friction material layer; And
And an engaging portion coupled to an upper surface of the fourth substrate and the buoy,
Wherein the engaging part moves the fourth substrate up and down by the motion of the buoy so that the fourth friction material layer is in contact with and does not contact the third friction material layer to generate triboelectricity.
12. The method of claim 11,
The triboelectric generating unit includes:
A second body having an inner space formed therein;
A third substrate fixed to a lower surface of the second main body;
A third electrode layer disposed on the third substrate;
A third friction material layer disposed on the third electrode layer;
A fourth friction material layer capable of contacting and non-contacting the third friction material layer;
A fourth electrode layer disposed on the fourth friction material layer;
A fourth substrate disposed on the fourth electrode layer; And
And an engaging portion coupled to an upper surface of the fourth substrate and the buoy,
Wherein the engaging part moves the fourth substrate up and down by the motion of the buoy so that the fourth friction material layer is in contact with and does not contact the third friction material layer to generate triboelectricity.
A buoy positioned on the sea surface and capable of at least one of up and down movement and rotation movement by waves and generating triboelectricity based on the movement; And
And a triboelectric generator positioned below the sea level and connected to the buoy to generate triboelectricity under the influence of motion of the buoy,
The buoy,
A first board fixed inside the buoy and disposed so as to pass through the center of rotation;
A plurality of first electrodes arranged to surround the central axis of the first substrate on the first substrate and spaced apart from each other along the rotation direction of the central axis;
First friction material layers disposed on the first electrodes, respectively;
A second substrate having the rotation axis passing through a center of the second substrate and connected to the second substrate and rotated together with the rotation axis;
A second electrode disposed on a lower surface of the second substrate;
One or more second friction material layers disposed on the bottom surface of the second electrode and disposed to surround the central axis of the second substrate and spaced apart from one another in the rotational direction of the central axis and contactable and non- ; And
And a weight placed on the upper surface of the second substrate in a state of being separated from the center of the second substrate,
Wherein the second friction material layers are capable of contacting and non-contacting the first friction material layers when the second substrate rotates due to the weight of the weight when the buoy moves.
15. The method of claim 14,
The triboelectric generating unit includes:
A second body having an inner space formed therein;
A third substrate fixed to a lower surface of the second main body;
A third electrode layer disposed on the third substrate;
A third friction material layer disposed on the third electrode layer;
A fourth friction material layer capable of contacting and non-contacting with the third friction material layer and serving as an electrode;
A fourth substrate disposed on the fourth friction material layer; And
And an engaging portion coupled to an upper surface of the fourth substrate and the buoy,
Wherein the engaging part moves the fourth substrate up and down by the motion of the buoy so that the fourth friction material layer is in contact with and does not contact the third friction material layer to generate triboelectricity.
15. The method of claim 14,
The triboelectric generating unit includes:
A second body having an inner space formed therein;
A third substrate fixed to a lower surface of the second main body;
A third electrode layer disposed on the third substrate;
A third friction material layer disposed on the third electrode layer;
A fourth friction material layer capable of contacting and non-contacting the third friction material layer;
A fourth electrode layer disposed on the fourth friction material layer;
A fourth substrate disposed on the fourth electrode layer; And
And an engaging portion coupled to an upper surface of the fourth substrate and the buoy,
Wherein the engaging part moves the fourth substrate up and down by the motion of the buoy so that the fourth friction material layer is in contact with and does not contact the third friction material layer to generate triboelectricity.
A buoy positioned on the sea surface and capable of at least one of up and down movement and rotation movement by waves and generating triboelectricity based on the movement; And
And a triboelectric generator positioned below the sea level and connected to the buoy to generate triboelectricity under the influence of motion of the buoy,
The buoy,
A first board fixed inside the buoy and disposed so as to pass through the center of rotation;
A plurality of first electrodes arranged to surround the central axis of the first substrate on the first substrate and spaced apart from each other along the rotation direction of the central axis;
The first friction material layers being disposed on the first electrodes and each of the first friction material layers being made of a material having a charging property different from the charging property of the adjacent first friction material layer, ;
A second substrate having the rotation axis passing through a center of the second substrate and connected to the second substrate and rotated together with the rotation axis;
A first substrate disposed on the lower surface of the second substrate and disposed to surround the central axis of the second substrate and spaced apart from one another in the direction of rotation of the central axis and contacting and noncontact with the first layers of friction material, 2 friction material layers; And
And a weight placed on the upper surface of the second substrate in a state of being separated from the center of the second substrate,
Wherein the second friction material layers are capable of contacting and non-contacting the first friction material layers when the second substrate rotates due to the weight of the weight when the buoy moves.
18. The method of claim 17,
The triboelectric generating unit includes:
A second body having an inner space formed therein;
A third substrate fixed to a lower surface of the second main body;
A third electrode layer disposed on the third substrate;
A third friction material layer disposed on the third electrode layer;
A fourth friction material layer capable of contacting and non-contacting with the third friction material layer and serving as an electrode;
A fourth substrate disposed on the fourth friction material layer; And
And an engaging portion coupled to an upper surface of the fourth substrate and the buoy,
Wherein the engaging part moves the fourth substrate up and down by the motion of the buoy so that the fourth friction material layer is in contact with and does not contact the third friction material layer to generate triboelectricity.
18. The method of claim 17,
The triboelectric generating unit includes:
A second body having an inner space formed therein;
A third substrate fixed to a lower surface of the second main body;
A third electrode layer disposed on the third substrate;
A third friction material layer disposed on the third electrode layer;
A fourth friction material layer capable of contacting and non-contacting the third friction material layer;
A fourth electrode layer disposed on the fourth friction material layer;
A fourth substrate disposed on the fourth electrode layer; And
And an engaging portion coupled to an upper surface of the fourth substrate and the buoy,
Wherein the engaging part moves the fourth substrate up and down by the motion of the buoy so that the fourth friction material layer is in contact with and does not contact the third friction material layer to generate triboelectricity.
18. The method of claim 17,
Wherein the first friction material layers are arranged such that materials having two different charging characteristics are alternately arranged.
21. The method of claim 20,
Wherein the material of the second layer of friction material is selected such that the charging property of the second layer of friction material on the triboelectric series is positioned between the charging characteristics of the first layers of friction material.
A buoy positioned on the sea surface and capable of at least one of up and down movement and rotation movement by waves and generating triboelectricity based on the movement; And
And a triboelectric generator positioned below the sea level and connected to the buoy to generate triboelectricity under the influence of motion of the buoy,
The buoy,
A first board fixed inside the buoy and disposed so as to pass through the center of rotation;
A plurality of first electrodes arranged to surround the central axis of the first substrate on the first substrate and spaced apart from each other along the rotation direction of the central axis;
The first friction material layers being disposed on the first electrodes and each of the first friction material layers being made of a material having a charging property different from the charging property of the adjacent first friction material layer, ;
A second substrate having the rotation axis passing through a center of the second substrate and connected to the second substrate and rotated together with the rotation axis;
A second electrode disposed on a lower surface of the second substrate;
One or more second friction material layers disposed on the bottom surface of the second electrode and disposed to surround the central axis of the second substrate and spaced apart from one another in the rotational direction of the central axis and contactable and non- ; And
And a weight placed on the upper surface of the second substrate in a state of being separated from the center of the second substrate,
Wherein the second friction material layers are capable of contacting and non-contacting the first friction material layers when the second substrate rotates due to the weight of the weight when the buoy moves.
23. The method of claim 22,
The triboelectric generating unit includes:
A second body having an inner space formed therein;
A third substrate fixed to a lower surface of the second main body;
A third electrode layer disposed on the third substrate;
A third friction material layer disposed on the third electrode layer;
A fourth friction material layer capable of contacting and non-contacting with the third friction material layer and serving as an electrode;
A fourth substrate disposed on the fourth friction material layer; And
And an engaging portion coupled to an upper surface of the fourth substrate and the buoy,
Wherein the engaging part moves the fourth substrate up and down by the motion of the buoy so that the fourth friction material layer is in contact with and does not contact the third friction material layer to generate triboelectricity.
23. The method of claim 22,
The triboelectric generating unit includes:
A second body having an inner space formed therein;
A third substrate fixed to a lower surface of the second main body;
A third electrode layer disposed on the third substrate;
A third friction material layer disposed on the third electrode layer;
A fourth friction material layer capable of contacting and non-contacting the third friction material layer;
A fourth electrode layer disposed on the fourth friction material layer;
A fourth substrate disposed on the fourth electrode layer; And
And an engaging portion coupled to an upper surface of the fourth substrate and the buoy,
Wherein the engaging part moves the fourth substrate up and down by the motion of the buoy so that the fourth friction material layer is in contact with and does not contact the third friction material layer to generate triboelectricity.
23. The method of claim 22,
Wherein the first friction material layers are arranged such that materials having two different charging characteristics are alternately arranged.
26. The method of claim 25,
Wherein the material of the second layer of friction material is selected such that the charging property of the second layer of friction material on the triboelectric series is positioned between the charging characteristics of the first layers of friction material.

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