KR20170142908A - Generator using isolation of vibration - Google Patents

Abstract

The present invention provides a vibration isolated generator using vibration isolation, which obtains electricity by modifying energy caused by vibration isolation to reduce vibration caused by an impact such as a building or a machine to which a vibration isolation structure is applied. The generator comprises: a vibration isolation body absorbing vibration energy of a vibrating body vibrated by an external impact, and causing a vertical deformation, a horizontal deformation, or a combination thereof; a large-diameter tube located inside the vibration isolation body, receiving a deformation of the vibration isolation body to change the shape thereof, and filled with a fluid therein; a small-diameter tube connected to the large-diameter tube, having a diameter smaller than the diameter of the large-diameter tube, and filled with a fluid; at least one electricity generation unit installed in the small-diameter tube, and generating electricity through electromagnetic induction by the flow of the fluid; and a check valve located between the large-diameter tube and the electricity generation unit, and flowing the fluid in one direction.

Description

{Generator using isolation of vibration}

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a generator, and more particularly, to an asynchronous generator for generating electricity by using a seismic wave, which is a process of reducing vibration caused by an impact.

Earthquakes, winds, and vibrations due to impacts from vehicles are always present in real life. In the case of buildings, trains, etc., a damper is used to reduce vibration due to impact. Various studies have been carried out for the purpose of seismic isolation to reduce vibrations. Basically, measurement techniques for standard weight impact sources are being developed. Generators are devices that convert mechanical energy into electrical energy and use a variety of sources to impart the mechanical energy. Korean Patent No. 10-1200916, and Korean Patent No. 10-1506836 disclose methods of generating power by using a load when a vehicle passes through the road.

However, the conventional method is difficult to apply to a seismic structure for reducing vibration caused by an impact of a building or a mechanical device. This is because the load of the building or machinery to which the seismic isolation structure is applied is very heavy compared with the vehicle, so that the method of transmitting the load by the spring is not applicable. As a result, there is no such generator that generates seismic energy as a source. If electricity is generated using wasted seismic energy, the economic value is very high.

A problem to be solved by the present invention is to provide a seismic generator using seismic isolation to obtain electricity by modifying energy caused by seismic excursions to reduce vibration caused by impacts of a building or mechanical device to which the seismic isolation structure is applied.

SUMMARY OF THE INVENTION [0008] The present invention provides a generator using a vibration isolator that includes a planar body that absorbs vibration energy of a vibrating body that vibrates due to an external impact and causes vertical deformation or horizontal deformation or deformation combined therewith, Diameter tube having a shape changing and a fluid filled therein, and a small-diameter tube connected to the large-diameter tube, the small-diameter tube having a diameter smaller than the diameter of the large-diameter tube and filled with the fluid. In addition, it is preferable that at least one of the small-diameter tubes is provided with an electricity generating portion for generating electricity by electromagnetic induction due to the flow of the fluid, and an electricity generating portion located between the large-diameter tube and the electricity generating portion, And a check valve for controlling the flow rate.

In the generator of the present invention, the planar body may be made of ethylene propylene rubber (EPR, EPDM), nitrile rubber (NBR), butyl rubber, halogenated butyl rubber, chloroprene rubber (CR), natural rubber (NR), isoprene rubber , Styrene butadiene rubber (SBR), butadiene rubber (BR), and mixtures thereof. The planar body may be formed by laminating a soft plate and a rigid plate in a plate form. The hard plate may be formed by laminating any one selected from metal, ceramics, plastic, FRP, polyurethane, wood, paper, slate, toilet stone and mixtures thereof. The soft plate may contain porous hard particles. The center of the laminate in which the soft plate and the hard plate are stacked may include a plug for absorbing vibration energy by plastic deformation and elastic deformation.

In the preferred generator of the present invention, the large-diameter tube and the small-diameter tube may be made of synthetic resin. The large-diameter tube and the small-diameter tube may be single-layered or multi-layered. The surface of the large-diameter tube may be provided with a locking protrusion along the circumference thereof. The surface of the large diameter tube may be corrugated. A bottleneck may be present between the large-diameter tube and the small-diameter tube. The large-diameter tube can be branched. The fluid may consist of water or oil.

In the generator of the present invention, the electricity generating portion may include a rotor rotated by the flow of the fluid. The electrical energy generated by the electricity generating unit may be stored in the power storage unit through the lead wire.

According to the generator using the seismic isolation of the present invention, the fluid is circulated in accordance with the vibration of the planar body to generate electricity, thereby modifying the energy generated by seismic isolation to reduce vibrations caused by impacts of buildings, machinery, Can be obtained.

FIG. 1 is a schematic view for explaining an seismic generator using seismic isolation according to the present invention.
2 is a cross-sectional view taken along the line AA in Fig.
3 is a cross-sectional view taken along the line BB in Fig.
4 is a perspective view for explaining an example of a cotton body applied to a seismic generator using the seismic isolation according to the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. The embodiments described below can be modified into various other forms, and the scope of the present invention is not limited to the embodiments described below. The embodiments of the present invention are provided to enable those skilled in the art to more fully understand the present invention. On the other hand, terms pointing to positions such as top, bottom, front, and the like only relate to those shown in the drawings. In practice, the seismic generator can be used in any optional orientation, and the spatial orientation in actual use varies with the position and rotation of the seismic generator.

In the embodiment of the present invention, the fluid is circulated in accordance with the vibration of the planar body to generate electricity, thereby generating energy by modifying the energy generated by the seismic vibration for reducing the vibration caused by the impact of buildings, . To this end, the structure of the seismic generator will be described in detail, and the process of generating electricity from the seismic generator will be described in detail. Here, seismic isolation refers to a measure against vibration that inserts an elastic material or the like in the middle of a propagation path in order to prevent vibration from propagating. These seismic isolations are applied to vibrators with relatively heavy loads, such as buildings, machinery, and so on. Of course, the seismic generator of the present invention may also be installed on the road on which the vehicle is traveling, or on the railway passing through the train.

FIG. 1 is a schematic view for explaining a seismic generator using seismic isolation according to an embodiment of the present invention, and FIG. 2 is a cross-sectional view taken along the line A-A of FIG.

Referring to FIGS. 1 and 2, the stator generator of the present invention includes a body 10, a first tube 20, and an electricity generator 30. The vibrating body 100 is placed on the surface 10 and the first tube 20 is divided into a large diameter tube 20a having a large diameter and a small diameter tube 20b having a small diameter. A part of the large diameter tube 20a is located inside the beveled body 10. The vibrating body (100) is a structure in which vibrations are induced by wind, earthquake, mechanical, or artificial such as buildings, machinery, and the like. The vibration of the vibrating body 100 may be perpendicular (z-direction) or horizontal (x-y) to the ground, or a combination thereof. In addition, the vibration may be irregular in amplitude or frequency or irregular in frequency. However, vibration caused by wind, earthquake, or the like is irregular, and vibration occurring mechanically or artificially is often regular.

The planar body 10 is a material that absorbs vibration of the vibrating body 100. When the vibration is absorbed, a vertical deformation or a horizontal deformation or a combination thereof occurs. The planar body 10 may be formed by laminating the rigid plate 10a and the flexible plate 10b in a plate form or by only the flexible plate 10b. The cotton body 10 is wrapped with a cover 11. The rigid plate 10a is for providing structural rigidity and is preferably not in direct contact with the large diameter tube 20a except for the upper and lower contact portions b and c. The upper and lower contact portions b and c allow the vibration to be transmitted to the large-diameter tube 20a. Of course, the upper and lower contact portions b and c may be in contact with the soft plate 10b rather than the rigid plate 10a. The hard plate 10a is not limited to the material to be applied, and may be made of metals, ceramics, plastic, FRP, polyurethane, wood, paper, slate, and toilet stone.

The flexible plate 10b can be designed differently depending on the position, such as the upper portion, the lower portion and the side surface of the large diameter tube 20a. In the example shown in the figure, the hard plate 10a is laminated on the upper and lower portions of the upper and lower contact portions b and c of the large diameter tube 20a, and only the soft plate 10b is present on the side surface. In some cases, the flexible plate 10b may not be laminated with the rigid plate 10a, but may fill the gap between the cover 11 and the large-diameter tube 20a. In this case, the planar body 10 is made of only the flexible plate 10b.

Various materials can be applied to the flexible plate 10b, and examples thereof include various kinds of vulcanized rubber, unvulcanized rubber, organic materials such as plastics, foams thereof, inorganic materials such as asphalt and clay, Can be used. In general, it is preferable to use a highly damped rubber for the face body 10. Examples of the highly damped rubber include ethylene propylene rubber (EPR, EPDM), nitrile rubber (NBR), butyl rubber, halogenated butyl rubber, chloroprene rubber (CR), natural rubber (NR), isoprene rubber (IR), styrene butadiene rubber ), Butadiene rubber (BR), and the like. Of these, halogenated butyl rubber, EPR, EPDM, CR, NR, IR, BR and SBR are preferable, and two or more kinds of them are more preferably blended.

 The soft plate 10b may contain hard particles 12 having a diameter of several millimeters to enhance structural rigidity. The hard particles 12 can increase the bonding property with the material constituting the soft plate 10b by utilizing the porous particles. The hard particles 12 may be, but are not limited to, glass beads, metal beads, synthetic resin beads, ceramic beads, and mixtures thereof. The flexible plate 10b may further include conductive particles such as carbon black to reduce the static electricity generated by the vibration.

The cover 11 is preferably a rubber polymer having excellent weather resistance, and examples thereof include butyl rubber, acrylic rubber, polyurethane, silicone rubber, fluorine rubber, polysulfide rubber, ethylene propylene rubber (ERP and EPDM), hypersuron, chlorinated polyethylene, Ethylene vinyl acetate rubber, epichlorohydrin rubber, and chloroprene rubber. Among them, particularly, butyl rubber, polyurethane, ethylene propylene rubber, hyperron, chlorinated polyethylene, ethylene-vinyl acetate rubber and chloroprene rubber are excellent in weather resistance. In consideration of adhesion with the cotton body 10, butyl rubber, ethylene propylene rubber and chloroprene rubber are preferable, and ethylene propylene rubber is particularly preferable. The cover 11 may be used alone or in combination of two or more. In addition, the cover 11 can be blended with various fillers, anti-aging agents, plasticizers, softening agents, oils and the like.

The first tube 20 is made of a material that is flexible to accommodate the deformation of the body 10 by vibration. The material of the first tube 20 is preferably a synthetic resin, and thermoplastic resin is particularly preferable. Examples of the thermoplastic resin include polyethylene terephthalate, polylactic acid, polyethylene, polypropylene, polycarbonate, polymethylmethacrylate, and polyvinyl chloride. The thermoplastic resin may be blended with an elastomer to improve flexibility. Of the elastomers, thermoplastic elastomers are preferred. The thermoplastic elastomer has a rubber property at room temperature, but gradually plasticizes at a high temperature to exhibit plastic characteristics. The thermoplastic elastomer is present in the form of an elastic rubber without cross-linking. Particularly, the olefinic thermoplastic elastomer is a material in which an olefinic resin such as polyethylene or polypropylene and an olefinic rubber (for example, EDPM or ethylene propylene diene monomer) are combined as a main component.

The first tube 20 may be a single layer, but may be formed of multiple layers. The multilayer case may be, for example, a coextrusion sheet of a linear low density polyethylene film and a low density polyethylene film, or a coextrusion sheet of a linear low density polyethylene film and a high density polyethylene film and a linear low density polyethylene film. Further, the coextruded sheet can be laminated again with an ethylene acrylic acid copolymer adhesive. Alternatively, a thin metal plate may be inserted between any of the layers of the multilayer. Such a metal plate can be inserted in a plate form or can be prepared by vapor deposition. In other words, the first tube 20 may be a single layer or a multilayer, and if it is a multilayer, the coextrusion sheet has an appropriate thickness, and if necessary, a metal plate is inserted to increase rigidity.

A plurality of locking portions 13 are provided on the surface of the large diameter tube 20a to increase the coupling force with the flexible plate 10b. The locking portion 13 protrudes along the periphery so that the soft plate 10b fits into the space formed by the protruded portion and is fixed so that the coupling force between the soft plate 10b and the large diameter tube 20a is increased. Further, the surface of the large-diameter tube 20a may have the corrugations 14 thereon. The corrugations 14 allow the deformation of the large diameter tube 20a due to vibration to occur more stably. Without the wrinkles 14, it is difficult to obtain a certain pattern for deformation of the large-diameter tube 20a, but if the wrinkles 14 are present, the pattern of deformation can be relatively uniformly adjusted.

The inside of the first tube (20) is filled with the fluid (22). The fluid 22 is preferably water or oil having excellent fluidity. In order to prevent oxidation of parts constituting the electricity generating section 30, oil is applied. Of course, the viscosity of the oil is set as low as possible within a range not limiting the flowability. The fluid 22 flows inside the first tube 20 in response to a change in shape of the large diameter tube 20a. This will be described later in detail.

The small diameter tube 20b of the first tube 20 is made by reducing the diameter of the large diameter tube 20a. Thereby, the bottleneck a exists between the large-diameter tube 20a and the small-diameter tube 20b. The diameter of the bottleneck (a) gradually decreases to prevent sudden pressure change. That is, the portion having the largest diameter of the bottleneck portion (a) is connected to the large diameter tube 20a, and the portion having the smallest diameter is connected to the small diameter tube 20b. That is, the bottleneck (a) has a funnel shape. In the small-diameter tube 20b, a check valve 21 is disposed on one side of the planar body 10. That is, the check valve 21 is positioned between the large diameter tube 20a and the electricity generating portion 30 in a predetermined position. The check valve 21 prevents the fluid 22 from flowing backward and flows only in one direction. The check valve 21 can select a suitable structure for a lift check, a swing check, an in-line type, an angle type, and the like.

At least one electric generating portion 30 is disposed in the small-diameter tube 20a at a predetermined interval. Electricity acquisition by the electricity generating unit 30 uses electromagnetic induction phenomenon. The magnitude of the electromotive force is proportional to the magnitude of the magnetic field, the length of the conductor, the relative speed of the magnetic field and the conductor, and the direction of the electromotive force can be known by the Fleming's right-hand rule . To construct the electric generating unit 30, a strong magnet for generating a magnetic field and a conductor generating an electromotive force are required, and either of them must be able to operate. The figure shows an example of using the electromagnetic induction phenomenon. This will be described in detail with reference to FIG.

Preferably, the electric energy converted by each electricity generating unit 30 is drawn out by a lead wire 41 connected to each electricity generating unit 30 and is supplied to a power storage unit 40 such as a capacitor or a charger . The capacitor is a device for collecting charges, such as a vacuum capacitor, an air capacitor, a metalized paper capacitor, and the like. Typically, the capacitor has a structure in which two metal plates are used as electrodes and a dielectric is interposed therebetween. The charger is a device for supplying electric energy to the battery and changing the energy into chemical energy. These chargers include a primary battery capable of discharging only, and a rechargeable secondary battery. The power storage unit 40 may store electric energy generated by the electricity generation unit 30 in various forms other than the above-described devices and systems.

3 is a cross-sectional view for explaining the electricity generating section 30 by cutting along the line B-B in Fig. Here, the electricity generating unit 30 is presented as one example, and other forms can be applied within the scope of the present invention. Further, since the electricity generating section 30 has described only essential elements, another element for generating electric power is added.

3, the electricity generating portion 30 is fixed to the rotating shaft 31 and includes a rotor 32 wound with a coil. The rotor 32 is located inside the small-diameter tube 20a and is rotated by the flow of the fluid 22. Although not shown in the drawings, the rotor 32 includes a brush, a commutator element, and the like, and has a structure that smoothly rotates in accordance with the flow of the fluid 22. The outside of the small-diameter tube 20b is provided with a stator 33 wound with a field winding 35 and an induction magnet 34 attached to the small-diameter tube 20b. As the rotor 32 rotates, a current is obtained in the field winding 35 by the electromagnetic induction phenomenon.

The seismic generator of the present invention generates electricity through the following process. Specifically, when the vibrating body 100 vibrates, the platy body 10 is deformed. When the planar body 10 is deformed, the shape of the first tube 20 is changed. When the shape of the first tube 20 is changed, the pressure in the large-diameter tube 20a increases. On the other hand, the check valve 21 causes the fluid 22 to flow in one direction, and the fluid 22 is discharged in the clockwise or counterclockwise direction toward the small-diameter tube 20b. Since the diameter of the small-diameter valve 20b is small, the velocity of the fluid 22 is increased by Bernoulli's theorem. At this time, the first tube 20 may have a means (not shown) capable of appropriately adjusting the pressure, for example, a buffer auxiliary tube or the like.

The fluid (22) rotates the rotor (32) of the electricity generating section (30) to generate electricity by electromagnetic induction phenomenon. The obtained electricity is stored in the power storage unit 40 via the lead wire 41. [ The electricity generating portion 30 can be disposed at various places of the small tube 20b, and thus the amount of electricity obtained can be further increased. The number of the electricity generating portions 30 is determined in consideration of the length of the small tube 20b, the speed of the fluid 22, and the like. The seismic generator according to the embodiment of the present invention can obtain electricity by modifying the energy by seismic isolation to reduce the vibration caused by the impact of a building or a mechanical device to which the seismic isolation structure is applied.

4 is a perspective view for explaining an example of a cotton body applied to a seismic generator using a seismic isolation according to an embodiment of the present invention. At this time, the example is similar to Figs. 1 and 2 except that the features of the cotton body 15 and the second tube 25 are different. Accordingly, a detailed description of overlapping portions will be omitted.

4, the planar body 15 has a vibration absorber 15e including a plug 15a, an elastic plate 15b, a rigid plate 15c, and a cover 15d. The vibration absorber 15e is located between the upper connecting plate 15f and the lower connecting plate 15g. The vibrating body 100 is placed on the upper connecting plate 15f and the lower connecting plate 15g is fixed to the floor like the ground by the bottom fixing portion 15h. The soft plate 15b and the rigid plate 15c are alternately laminated layers 15b and 15c and the soft plate 15b and rigid plate 15c are made of the soft plate 10b and rigid plate 10a, Have the same material and characteristics.

The plug 15a absorbs vibration energy by firing and elastic deformation when the stacked bodies 15b and 15c are deformed by vibration. The plug 15a is made of a metal material such as lead or a synthetic resin. In the case of a metal material, the alloy may be applied to a material having a low melting point such as tin. In the case of a synthetic resin, it is possible to reduce the impact by mixing the elastomer components, to reduce the static electricity by mixing the conductive powder or the like, and to reduce the thermal shock by adding graphite or the like. The plug 15a may have a single-layer or multi-layer structure, and the layer structure is appropriately designed in consideration of the size of the seismic generator of the present invention, the environment in which it is used, and the like.

The cover 15d is as shown in the cover 11 of Fig. 2, and various fillers, anti-aging agents, plasticizers, softeners, oils and the like are incorporated according to circumstances. The upper and lower connecting plates 15f and 15g are made of a single layer or a multilayer of a metal having high rigidity. A bolt or the like is used for the bottom fixing portion 15h. In this case, the vibration absorber 15e is connected to the vibrating body 100 via the upper connecting plate 15f, and is fixed to the floor by the lower connecting plate 15g.

The seismic generator utilizing the vibration absorber 15e may have a second tube 25 penetrating the laminate 15b, 15c. The second tube 25 is composed of a branched large-diameter tube 25a and a small-diameter tube 25b. Like the first tube 20, the bottleneck a exists. Unlike the illustrated example, the large-diameter tube 25a is not branched and can be made of only one large-diameter tube 25a. At this time, the process of generating electricity using the cotton body 15 and the second tube 25 is as described above. Accordingly, the seismic generator using the vibration absorber 15e includes the electricity generating portion 30 and the check valve 21. [

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, but many variations and modifications may be made without departing from the spirit and scope of the invention. It is possible.

10, 15; Cotton body
10a, 15c; Rigid plate
10b, 15b; Soft plate
11, 15d; cover
12; Hard particles 13; Locking
14; Wrinkles 15a; plug
15e; Vibration absorber
20, 25; The first and second tubes
20a, 25a; Large diameter tube
20b, 25b; Small-diameter tube
21; Check valve 22; Fluid
30; Electricity generation unit 31; Rotating shaft
32; Rotor 33; The stator
34; Induction magnet 35; Field winding
40; A power storage unit 41; Lead wire

Claims (15)

A planar body which absorbs vibration energy of a vibrating body vibrating due to an external impact and causes a vertical deformation or a horizontal deformation or a combination thereof;
A large diameter tube which is located inside the cotton body and receives a deformation of the cotton body to change its shape and which is filled with a fluid;
A small diameter tube connected to the large diameter tube and having a diameter smaller than the diameter of the large diameter tube and filled with the fluid;
At least one of the small diameter tubes is provided with an electricity generating part for generating electricity by electromagnetic induction due to the flow of the fluid; And
And a check valve disposed between the large-diameter tube and the electricity generating unit for flowing the fluid in one direction. The method according to claim 1, wherein the cotton body is selected from the group consisting of ethylene propylene rubber (EPR, EPDM), nitrile rubber (NBR), butyl rubber, halogenated butyl rubber, chloroprene rubber (CR), natural rubber (NR), isoprene rubber A styrene-butadiene rubber (SBR), a butadiene rubber (BR), and a mixture thereof. 2. The seismic generator according to claim 1, wherein the planar body is formed by laminating a soft plate and a rigid plate in a plate shape. 4. The seismic generator according to claim 3, wherein the hard plate is formed by laminating any one selected from metal, ceramics, plastic, FRP, polyurethane, wood, paper, slate, The seismic generator according to claim 3, wherein the soft plate contains porous hard particles. 4. The seismic generator as set forth in claim 3, wherein the center of the laminate in which the soft plate and the hard plate are stacked includes a plug for absorbing vibration energy due to firing and elastic deformation. The seismic generator according to claim 1, wherein the large-diameter tube and the small-diameter tube are made of synthetic resin. 2. The seismic generator according to claim 1, wherein the large-diameter tube and the small-diameter tube are single-layered or multi-layered. [2] The seismic generator according to claim 1, wherein the surface of the large diameter tube is provided with a locking protrusion along the circumference thereof. The seismic generator according to claim 1, wherein the surface of the large-diameter tube is wrinkled.
The seismic generator according to claim 1, wherein a bottleneck is present between the large-diameter tube and the small-diameter tube. The seismic generator according to claim 1, wherein the large-diameter tube is branched. 2. The seismic generator according to claim 1, wherein the fluid is water or oil. 2. The seismic generator according to claim 1, wherein the electricity generating portion includes a rotor rotated by the flow of the fluid. 2. The seismic generator according to claim 1, wherein the electric energy generated in the electricity generating unit is stored in the electric power storage unit through the lead wire.

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