KR101730253B1 - Elastic tube type energy harvesting apparatus - Google Patents

Abstract

In order to attain the above object, the elastic tube type energy harvesting apparatus according to the present invention has an annular shape in which a space is formed inside and has an inner diameter gradually increasing between inner surfaces facing each other, and is made of a material having elasticity A first elastic tube; The first elastic tube is connected to the first elastic tube and the inner diameter between the inner surfaces facing each other is gradually increased, and a portion connected to the first elastic tube is taken as an axis, A second elastic tube formed of a material having elasticity so that approaching and separating can be repeated; And at least one of the first elastic tube and the second elastic tube so as to enable energy harvesting by triboelectrification in a process of repeatedly approaching and separating between the first elastic tube and the second elastic tube, And a main body provided on the at least one inner surface so as to reduce a mutual influence with the main body.

Description

[0001] The present invention relates to an elastic tube type energy harvesting apparatus,

The present invention relates to an elastic tubular energy harvesting apparatus, and more particularly, to an elastic tubular energy harvesting apparatus capable of securing a relatively large frictional area for triboelectrification even in a narrow space and reducing the mutual influence with various external environments, To an elastic tubular energy harvesting apparatus having an improved structure.

Recently, energy depletion due to indiscreet use of fossil fuels, environmental pollution caused by greenhouse gas emissions, and human health hazards have been raised as serious social issues. Therefore, not only are the conversion efficiencies to electric energy as high as fossil fuels in the world, but also researches for environmentally friendly and sustainable alternative energy are being actively pursued. In addition, Korea, which has less than 3% of energy independence, depends on fossil fuels for most of the systems, and development of alternative energy is more urgent.

In this background, research on energy harvesting technology that harvests the energy that is abandoned in the surrounding environment of light, heat, and vibration is actively conducted. In the energy harvesting technology, energy harvesting by temperature difference , Harvesting of light energy, energy harvesting by electromagnetic field change, and energy harvesting by electrostatic induction phenomenon caused by triboelectricity. Among the methods of harvesting such mechanical energy, energy harvesting using triboelectric energy has been reported to produce larger energy than piezoelectric and thermoelectric energy harvesting.

In addition to the nano generators that develop through the vertical contact-separation method between the triboelectrification materials in the triboelectric nano generators, the nano generators can be manufactured by various methods such as a horizontal contact-separation method and a single- Development is underway.

As best shown in FIGS. 1 and 2, most conventional tactile-separation type triboelectric nano generators have used springs 101 or spacers for contact and separation between friction surfaces. So far, various researches have been carried out to increase the efficiency of the nano generator. However, it has been recognized that the area for the spring and the spacer in the friction surface is indispensable for the contact and separation between the friction surfaces.

However, the area occupied by the spring and the spacer reduces the area over which friction can occur, which results in reduced efficiency. Conventional studies to increase energy harvesting efficiency by triboelectric charging have focused on the development of new mechanisms and materials. Therefore, the area occupied by the spring and the spacer has been taken for granted rather than the loss of the friction area. However, it has become necessary to develop a product that can increase the efficiency of energy harvesting by devising a product that can get a large friction area instead of a spring and a spacer instead of such stereotypes.

In addition, conventional triboelectric power plants are affected by various external environments such as humidity, presence of chemical substances, and peripheral electronic devices. In addition, since the triboelectric nano generator is a generator that generates electricity through the principle of friction charging, electrostatic discharge phenomena such as spark discharge where static electricity is discharged may occur. However, by devising a product capable of solving these problems, a realistic solution is needed in terms of practical use of the triboelectric nano generator.

SUMMARY OF THE INVENTION The present invention has been made in order to solve the above-mentioned problems, and it is an object of the present invention to provide a large frictional area for friction charging even in a narrow space and to minimize mutual influences with humidity, And to provide an elastic tube-type energy harvesting device which enables the energy-harvesting device to be installed.

In order to attain the above object, the elastic tube type energy harvesting apparatus according to the present invention has an annular shape in which a space is formed inside and has an inner diameter gradually increasing between inner surfaces facing each other, and is made of a material having elasticity A first elastic tube; The first elastic tube is connected to the first elastic tube and the inner diameter between the inner surfaces facing each other is gradually increased, and a portion connected to the first elastic tube is taken as an axis, A second elastic tube formed of a material having elasticity so that approaching and separating can be repeated; And at least one of the first elastic tube and the second elastic tube so as to enable energy harvesting by triboelectrification in a process of repeatedly approaching and separating between the first elastic tube and the second elastic tube, And a main body provided on the at least one inner surface so as to reduce a mutual influence with the main body.

The present invention is characterized by comprising an inner space formed with the first elastic tube and the second elastic tube, and an upper cap and a lower cap connected to any one of the first elastic tube and the second elastic tube, And at least one of the inner surfaces of the upper cap and the lower cap facing each other, wherein the upper and lower caps are in contact with each other when the upper and lower caps approach each other .

The present invention is characterized in that at least one of the upper cap and the lower cap and the upper cap and the lower cap are separated from each other in order to provide an elastic force separately from the first and second elastic tubes, And an elastic body provided between all the sub-bars.

The present invention may have a structure in which the main base is provided on the inner surfaces of the first elastic tube and the second elastic tube, respectively, and when the first elastic tube and the second elastic tube approach each other, And an electrode provided between the first elastic tube and the second elastic tube so as to increase the energy harvesting efficiency by making contact with the entire body at the same time.

The elastic tube type energy harvesting apparatus according to the present invention having the above-described structure replaces the pair of elastic tubes by a spring, unlike the conventional method in which the pair of bases are frictioned with each other by the conventional spring type, It is possible to prevent the reduction of the friction area which is necessarily caused by the spring, the spacer, and the like. As a result, since the elastic tubes not only provide the elastic force for friction but also cause the friction itself, Can be relatively large.

Further, the elastic tube type energy harvesting apparatus according to the present invention has a structure in which the entire base causing the triboelectric charging is positioned in a space which is almost closed (airtight enough to allow air in and out) by elastic tubes, It is possible to minimize the influence of various external environments such as materials or peripheral parts and to suppress the phenomenon of electrostatic discharge (electrostatic discharge) like a spark due to interference between the whole main body and an external object at the time of tribo charging .

1 and 2 are schematic cross-sectional views of an energy harvesting apparatus according to the prior art as compared with the present invention.
3 is a partial cutaway perspective view of an elastic tubular energy harvesting device in accordance with an embodiment of the present invention.
4 is a cross-sectional view of one embodiment of the present invention.
5 is a conceptual diagram for explaining the principle of an embodiment of the present invention.
6 is a cross-sectional view of an elastic tubular energy harvesting device according to another embodiment of the present invention.
7 is a cross-sectional view of an elastic tubular energy harvesting apparatus according to another embodiment of the present invention.
8 is a cross-sectional view of an elastic tubular energy harvesting apparatus according to another embodiment of the present invention.

Hereinafter, an elastic tube type energy harvesting apparatus according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

FIG. 3 is a partially cutaway perspective view of an elastic tubular energy harvesting apparatus according to an embodiment of the present invention, FIG. 4 is a cross-sectional view of an embodiment of the present invention, and FIG. 5 is a conceptual diagram for explaining the principle of an embodiment of the present invention.

As shown in these drawings, the elastic tube type energy harvesting apparatus according to an embodiment of the present invention is manufactured in the form of a tube (or bellows) having elasticity by causing triboelectric charging in a vertical contact- , A first elastic tube (11), a second elastic tube (12), and a main base (13).

The first elastic tube (11) has an annular shape so as to form a space on the inner side thereof. The first elastic tube (11) has a structure in which the inner diameter between the inner surfaces facing each other gradually increases, and elastic deformation such as rubber or synthetic resin It is made of possible material.

The second elastic tube 12 is formed of the same material as the first elastic tube 11 and connected to the first elastic tube 11 so that the inner diameter between the inner surfaces facing each other is gradually increased.

The first elastic tube 11 and the second elastic tube 12 can be restored to their original positions even after the external force has been released since the elastic force of the material itself causes the external force to come close to each other .

As described above, according to the present embodiment, when the elastic tubes 11 and 12 are compressed and relaxed by using the elastic tubes 11 and 12 having elasticity of the material itself in place of the conventional springs and spacers, So that energy harvesting can be obtained within the elastic tubes 11 and 12 themselves.

The first elastic tube 11 and the second elastic tube 12 may be formed separately and connected to each other. However, the first elastic tube 11 and the second elastic tube 12 may be integrally formed for convenience of manufacturing and smoothness of elasticity .

The main base 13 is provided on at least one of the first elastic tube 11 and the second elastic tube 12 and is made of a material which is easily positively charged or is easily charged Material can be variously implemented. In this embodiment, as shown in FIG. 4, a material easily charged with negative charge is applied to the second elastic tube 12 by coating, coating or bonding Respectively.

Examples of the material which is liable to be positively charged with (+) include polymer, metal and the like, and the material which is likely to be positively charged includes polymer, PDMS, Teflon and the like. Means that the charge of the opposite sign is mechanically split by interference. Friction charging effects are more pronounced as the materials with opposite polarity (chargeability) are frictioned.

The triboelectric nano generator is an energy harvesting device that increases the actual contact area when materials come into contact with each other even when the apparent area is the same, by forming the friction surface with a microstructure such as a nano structure.

In order to allow the triboelectric charging effect to occur well, there is a method of raising the frequency of occurrence of the triboelectrification effect by rubbing a material having an opposite polarity (electric charge) to each other as mentioned above. However, There is also a method of increasing the density at which the triboelectrification effect occurs by increasing the area itself.

In order to form micro / nano structure in PDMS which is easy to be charged with (-), PDMS with nanowire structure can be obtained by applying HDFS to anodized aluminum having nanohole structure, drying PDMS, and drying. In addition, PDMS can be obtained by simultaneously anodically oxidizing the microstructure of aluminum by sandblasting and replicating it with PDMS.

In this way, existing domestic and overseas research groups use polymer materials that are easily charged with (+) or (-) as a triboelectrification material and generate nanostructures such as nanowires on the surface to maximize the contact area The research has focused on the increase of the output and application of the triboelectric nano generator.

However, there is a limit to improving the output by increasing the contact area through the nanostructure approaching only the material aspect. In order to develop a high-efficiency nano generator for obtaining a larger energy harvest, the area of the actual friction surface must increase not only in the increase of the contact area through the nanostructure.

According to the embodiment of the present invention having the above-described structure, by using a pair of elastic tubes 11 and 12 instead of the spring, it is possible to increase the area where friction occurs. In addition, a pair of elastic tubes 11 and 12 having elasticity of the material itself provide a power source for up and down movement for friction charging instead of a spring, and a pair of elastic tubes 11 and 12 Additional energy harvesting can be achieved by using friction between the contact surfaces and the separation between the contact surfaces.

One embodiment of the present invention has been described above with reference to Figs. 3 to 4. Fig. Reference numerals 16 and 17 in the drawings denote a first elastic tube 11 and a second elastic tube 12 so as to close the inner space formed by the first elastic tube 11 and the second elastic tube 12, 12, and 14, 15 are electrodes for harvesting energy by triboelectrification.

5, the principle of electric energy harvesting through the up-and-down contact-separating method is that when the main body 13, which is the first charged material, comes into contact with the electrode 15, Electrons move to the electrode 15 and are charged (see Fig. 5 (a)).

As the distance between the charged material (13) and the electrode (15) is increased while maintaining the equilibrium state, the polarity of the material caused by the electrostatic induction phenomenon changes to the electrode, Free electrons move from the electrode 15 to the opposing electrode 14 (see FIG. 5 (b)). (See Fig. 5 (c)), and when the two electrodes 14 and 15 are brought close to each other due to the external force, the electrons between the two electrodes 14 and 15 Movement occurs and an electric current is generated (see Fig. 5 (d)). Therefore, the current flows in the form of an alternating current each time the two electrodes 14 and 15 of the power plant repeat contact and separation.

In the meantime, the main base 13 used in one embodiment of the present invention is provided on the inner surface of the second elastic tube 12 so that the first elastic tube 11 and the second elastic tube 12 (Airtight enough to be allowed into and out of the air). In this case, it is possible to minimize the influence of various external environments such as humidity, chemical substances, and peripheral parts, and it is possible to prevent electrostatic discharges (electrostatic discharges) such as sparks due to interference between the main body 13 and the external object, discharge phenomenon can be suppressed.

Hereinafter, other embodiments of the present invention will be described.

6 is a cross-sectional view of an elastic tubular energy harvesting apparatus according to another embodiment of the present invention.

The embodiment shown in this figure has an upper cap 26 and a lower cap 27 which together form a first space 21 and a second space 22, (261) provided on at least one of the sub bands (261).

In this embodiment, the sub base 261 is provided on one of the upper and lower caps 26 and 27, i.e., the upper cap 26, Contact with and separation from the electrode 272 provided on the electrode 272 causes friction charging.

In this manner, in addition to the frictional charging between the first elastic tube 21 and the second elastic tube 22, the upper cap 26, which moves together with the elastic tubes 21 and 22 during vertical movement, And the lower cap 27 to enable the energy harvesting efficiency to be further increased.

In the drawing, reference numeral 262 denotes an electrode for harvesting energy by triboelectrification.

7 is a cross-sectional view of an elastic tubular energy harvesting apparatus according to another embodiment of the present invention.

The embodiment shown in this figure includes an elastic body 363 (373) provided between at least one of the upper and lower caps 36 and 37 and the entire sub-frame 361.

The elastic members 363 and 373 are made of elastic material such as rubber or sponge so that the elastic members 363 and 373 are restored to their original positions after approaching between the upper and lower caps 36 and 37, And acts to impart an elastic force to the elastic tubes 31 and 32 separately.

In the present embodiment including the elastic members 363 and 373, the sub-base 361 provided in the upper cap 36 is provided separately from the main base, thereby enhancing energy harvesting efficiency The upper cap 36 and the lower cap 37 can be designed to be in contact with each other due to the buffering action of the elastic bodies 363 and 373 so that the reaction efficiency can be further improved do.

Reference numerals 362 and 372 denote electrodes for harvesting energy by friction charging.

8 is a cross-sectional view of an elastic tubular energy harvesting apparatus according to another embodiment of the present invention.

The embodiment shown in this figure is characterized in that the main base 43 is provided on the inner surfaces of the first elastic tube 41 and the second elastic tube 42 respectively and the first elastic tube 41 and the second elastic tube 42, When the first elastic tube 41 and the second elastic tube 42 approach and separate from each other by providing the electrode 45 between the tubes 42, Contact between the first elastic tube (41) and the second elastic tube (42), thereby causing two frictional electrification during one approaching and separating operation of the first elastic tube (41) and the second elastic tube (42).

While the present invention has been described with reference to exemplary embodiments, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, but, on the contrary, Do.

11: first elastic tube 12: second elastic tube
13: main base whole 14, 15: electrode
16: upper cap 17: lower cap

Claims (4)

A first elastic tube formed in an annular shape so as to form a space inside and having a structure in which an inner diameter between inner surfaces facing each other gradually increases, and is made of a material having elasticity;
The first elastic tube is connected to the first elastic tube and the inner diameter between the inner surfaces facing each other is gradually increased, and a portion connected to the first elastic tube is taken as an axis, A second elastic tube formed of a material having elasticity so that approaching and separating can be repeated; And
Wherein the elastic tube is provided in at least one of the first elastic tube and the second elastic tube so as to enable energy harvesting by triboelectrification in the process of repeatedly approaching and separating the first elastic tube and the second elastic tube, And a main body provided on the at least one inner surface so as to reduce mutual influence of the main body,
And an upper cap and a lower cap connected to one of the first elastic tube and the second elastic tube to form an inner space together with the first elastic tube and the second elastic tube,
And at least one of the inner surfaces of the upper and lower caps opposing to each other in the process of the upper cap and the lower cap approaching each other,
The upper cap and the lower cap can be elastically separated from the first and second elastic tubes in the process of restoring to the original position after the approach between the upper cap and the lower cap, Further comprising an elastic body provided between at least any one of the upper cap and the lower cap and the entire sub-bar so as to increase the height of the upper and lower caps. delete delete The method according to claim 1,
Wherein the main base is provided on the inner surfaces of the first elastic tube and the second elastic tube,
And a second elastic tube disposed between the first elastic tube and the second elastic tube so that the first elastic tube and the second elastic tube are simultaneously brought into contact with each other when the first and second elastic tubes approach each other, And an electrode. The elastic tube type energy harvesting apparatus according to claim 1,

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