KR101456416B1 - Wave power generating apparatus for light buoy - Google Patents

Abstract

The present invention relates to a wave power generation device for a lighted buoy wherein a generator using wave power is disposed in a lighted buoy installed on the sea to assist in safe sailing of a ship in order to stably supply power source used in the lighted buoy. A lighted buoy for ocean route display includes a swing motion generation unit installed at a buoy body to generate force using a horizontal swing motion occurred by waves, and a vertical motion generation unit generating force using a vertical motion, which separately generate power, thereby improving efficiency of the wave power generation device to stably supply the power source used in the lighted buoy.

Description

[0001] The present invention relates to a wave power generating apparatus for a light buoy,

More particularly, the present invention relates to a wave power generator for a light buoy, and more particularly, to a light buoy for installing a light buoy to provide stable supply of power to be used in a light buoy, And more particularly,

In general, light buoys are mainly used for navigation of vessels to be used for navigation of ships, and are installed in clean waters and aquaculture waters, and are used to display objects such as reefs, submarine structures, sinking vessels, And is anchored to the sea floor as an anchor.

These lightbuoys are distinguished as having horn, blinking, and blending functions in cylindrical shape, mesh shape, cylinder shape, cone shape, etc. Light buoys include a satellite navigation system for confirming the position through display lamp and GPS module, And transmission and the like are installed and electric power is supplied by the built-in battery. However, there is an inconvenience that the battery needs to be replaced frequently.

In view of this, prior arts include photovoltaic power generation means or wind power generation means such as "light buoys using solar energy" of Patent No. 10-0804549 and "buoy construction with vertical solar cells" of Patent No. 10-1343482 Or in a combined form, to supply the power used for the light buoys.

As described above, the electric power source installed in the light-buoy for the navigation sign is self-generated and used, and therefore, even if a small amount of power is supplied, the power supply must be continuously supplied. It is an important part that requires more than a certain amount of continuous development.

Therefore, recently, it is necessary to provide a technique capable of increasing the power generation efficiency in the wave power generation while making it possible to supply the stable electric power by the wave power generation which can be used in parallel with the solar power generation or wind power generation installed in the light buoy.

SUMMARY OF THE INVENTION The present invention has been made in order to solve such a problem, and it is an object of the present invention to provide a buoyancy generator and a vertical motion generator in a buoy body for power generation using wave power, Wherein the eccentric rotor is provided on the horizontal guide rail and the eccentric rotator is mounted on the horizontal guide rail, the eccentric rotor rotates along the horizontal guide rail when the swing guide is horizontally moved by the wave, Wherein the up-down motion generator is slidably connected to the up-and-down guide body in the up / down tube body vertically moving together with the up / down motion generator, so that the up / down motion generator is vertically guided, Weight up and down movement and additional weights By using a vertical motion energy of the vertical lifting tube which tube is caused by the phase difference of the induced buoyancy lifting body by blue light buoy it has a wave power apparatus with improved power generation efficiency by ensuring a continuous power generation performed to provide.

The present invention relates to a light indicator for a route display, comprising: a swing motion generating part provided in a buoy body and generating power by using a horizontal swinging motion by wave; A swing guide base provided on the upper surface of the swing guide rail and having a horizontal guide rail in an arc shape on the upper surface thereof, The eccentric rotor for performing the motion and the central rotary shaft connected to the rotary power transmitting plate formed inside the eccentric rotor are installed on the central axis line of the rotary guide bar and are rotated by the rotary power transmitted to the central rotary shaft, A first power transmitting member; A lifting induction buoyant body slidably connected to an inner wall surface of the lifting tube body and having a second power transmission member fixed therein; a weight weight connected to a lower end of the lifting induction buoyancy body; A rotation induction guide bar vertically downwardly installed at an inner upper center of the lifting and lowering pipe body and having a retaining gear formed on both sides thereof and a third and fourth driven gears meshing with the both side face gear gears, And a second power transmitting member for generating power from the second generator by rotational power for rotating the fourth driven gear.

The swing guide is fixed to the inside of the buoy body and is provided as a ring-shaped plate having a horizontal shape, a horizontal guide rail is provided on the upper surface thereof, and a first power transmission member including a first generator is installed at the center of the swing guide .

The eccentric rotor is provided with a weight bearing and is provided with a rolling bearing for minimizing frictional resistance with the horizontal guide rail.

The first power transmitting member includes a driving gear provided on a central rotary shaft, a first driven gear engaged with the driving gear, a second driven gear engaged with the first driven gear to change the rotational direction, The first and second driven gears include first and second driven shafts provided with first and second clutch bearings for selectively generating rotational power, and first and second driven gears provided at the other end of the first and second driven shafts The first and second power transmission gears are coupled to both sides of the first power transmission gear provided on the first power generation shaft of the first generator so that rotational power can be transmitted to the first power transmission gear in one direction.

The first power transmitting member includes a drive gear provided on a central rotation axis, first and second driven gears coupled to both sides of the drive gear, first and second driven gears provided with first and second clutch bearings, And a first power transmission shaft provided with first and second driven gears provided at the other ends of the first and second driven shafts, And is engaged with both sides of the gear.

The lifting and lowering body is fixedly installed at a lower portion of the swing motion generating portion and is vertically moved along the buoy body.

The lifting induction buoyant body is provided with a second power transmission member for generating power from the second generator by a rotational power transmitted by the third and fourth driven gears, .

The weight is provided as a weight on the lower end of a connecting rod vertically connected to the lifting induction buoyant body, and the weight of the weight can be removed and attached to adjust the installation weight.

The rotation inducing guide is provided on a vertically moving body that moves up and down along the buoy body and the third and fourth driven gears of the second power transmitting member are engaged with the rec gear formed on both sides in the longitudinal direction of the rotation guide bar .

The second power transmitting member includes third and fourth driven gears respectively engaged with the both side surface gear gears, and third and fourth clutch bearings provided on the third and fourth driven gears to selectively rotate the third, And the third and fourth driven gears are provided on the other end of the third and fourth slave coaxial shafts and are engaged with both sides of the second power transmission gear provided on the second power generating shaft of the second generator .

The present invention relates to a buoyancy wave power generation device of a buoy type, comprising a buoyancy generating unit and a vertical motion generating unit provided on a buoy body, respectively, so that buoyancy is horizontally oscillated by a wave to achieve continuous power generation, It is possible to increase the power generation efficiency of the wave power generator by means of successive power generation by using the up and down motions, and it is possible to stably supply the power source used for the light level indicator.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a front view showing an overall configuration example of a light guide plate to which a wave power generator of the present invention is applied. FIG.
2 is a perspective view showing a configuration of a backlight wave power generator according to the present invention;
3 is a cross-sectional view showing a configuration of a backlight wave power generator according to the present invention.
4 is an enlarged perspective view of a part of a swinging motion generating portion in a backlight wave power generator according to the present invention;
5 is a partially enlarged cross-sectional view of a swinging motion generating portion in a backlight wave power generating device according to the present invention.
6 is a partially enlarged perspective view of a vertical movement generating section in the backlight wave power generating device according to the present invention.
7 is an enlarged cross-sectional view of a part of the vertical movement generating section in the backlight wave power generator according to the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. In the following description of the present invention, detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear.

In general, the light-guide 100 is installed on the sea to assist the safe navigation of the ship. The light-guide 100 includes a buoy body 110 floating on the sea surface, and a pylon column on the buoy body 110 A structure 120 is installed, and a display lamp, various communication facilities, a photovoltaic power generation device, a power supply system, and the like are installed in the structure 120.

The present invention relates to a buoyancy generator (200) for generating power using a buoyancy body (110) of a buoy 100 (100) by installing a wave power generator and horizontally swinging by wave; And a vertical movement generating unit 300 for generating power by using vertical up and down movement by waves. The power generating unit 300 is provided with continuous power generation, thereby improving power generation efficiency.

The rocking motion generator (200) comprises: A swing guide 210 mounted on the horizontal guide rail 216 to rotate along the horizontal guide rails 216 and to be eccentrically rotated by a weight, The end of the electron 220 and the rotational power transmitting plate 224 formed inside the eccentric rotor 220 are connected to the center rotational axis 226 and the center rotational axis 226 is connected to the center axis 226 of the oscillating guide 210. [ And a first power transmitting member 230 installed on the ship for power generation by the first generator 240 by a rotational power transmitted to the center rotary shaft 226. [

The rocking guide 210 is fixed to the inside of the buoy body 110 and is vertically formed as a ring-shaped plate horizontally. The rocking guide 210 is interconnected by a support 214. The rocking guide 210, which is an upper ring- And a first power transmitting member 230 including a first generator 240 is installed at the center of the swing guide 210. [

The eccentric rotor 220 is provided in a part of the horizontal guide rail 216 and is rotatable as an eccentric body so that when the swing guide 210 is horizontally moved, And a weight member for continuously rotating the eccentric rotor 220 using a downward force transmitted to the downward portion of the rail 216 to generate a strong rotational force such as a flywheel, The eccentric rotor 220 is preferably provided with a rolling bearing 222 for minimizing frictional resistance with respect to the horizontal guide rail 216 so that the rotary motion can be smoothly performed.

The eccentric rotor 220 is provided with a face plate having an angle of about 120 with respect to the center rotational axis 226 so as to exhibit the maximum eccentricity. However, the present invention is not limited thereto, It is needless to say that the present invention can be applied to any configuration capable of exhibiting the maximum eccentricity.

The first power transmitting member 230 includes a driving gear 232 provided on the central rotation shaft 226, a first driven gear 234 engaged with the driving gear 232, The first and second driven gears 234 and 234 'are provided with the first and second clutch bearings 236 and 236', and the second driven gear 234 ' The first and second driven shafts 235 and 235 'selectively generate rotational power. The first and second driven shafts 235 and 235' The first power transmission gear 244 is coupled to both sides of the first power transmission gear 244 provided on the first power generation shaft 242 of the first generator 240, So that it can transmit rotational power.

The first and second clutch bearings 236 and 236 'are disposed on both sides of the eccentric rotor 220 when the eccentric rotor 220 is rotated along the horizontal guide rail 216 of the swing guide 210, The first clutch gear 234 of the first driven gear 234 or the first clutch gear 234 of the first driven gear 234 is rotated in the clockwise or counterclockwise direction, The first and second driven shafts 235 and 235 'are selectively rotated by the second clutch bearing 236' of the second driven gear 234 ' 1 power transmission gear 244 to transmit rotation power in one direction to perform continuous power generation.

That is, according to various swinging conditions such as a position placed on the horizontal guide rail 216 and irregular horizontal swinging of the wave, the rotation of the eccentric rotor 220 in which the rotation direction of the eccentric rotor 220 in the clockwise or counterclockwise direction is changed The first driven gear 234 meshed with the drive gear 232 when the drive gear 232 provided on the central rotary shaft 226 also rotates in the clockwise or counterclockwise direction to transmit the rotational power, Of the second driven gear 234 'which engages with the first driven shaft 235 rotated by the first clutch bearing 236 of the first clutch gear 236 or the first driven gear 234 to change the rotational direction, To rotate selectively the second driven coaxial shaft 235 'rotated by the second driven coaxial shaft 235'.

When the eccentric rotor 220 rotates clockwise along the horizontal guide rail 216 to transmit the rotational force to the driving gear 232, the first driven gear 234 engaged with the driving gear 232, The power of the first generator 240 coupled to the first driven gear 238 of the first driven shaft 235 by the means for rotating the first driven shaft 235 by the first clutch bearing 236 while rotating The second driven gear 234 'engaged with the first driven gear 234 is brought into an idle state while the eccentric rotor 220 is rotated counterclockwise The first driven gear 234 coupled to the drive gear 232 is brought into the idle state and is engaged with the first driven gear 234 to change the rotational direction The second driven gear 234 'is connected to the second driven shaft 235' by a means for rotating the second driven shaft 235 'by the second clutch bearing 236' The power transmission gear 244 of the first generator 240 is rotated by the second driven gear 238 'of the eccentric rotor 220 to rotate the eccentric rotor 220 in the clockwise or counterclockwise direction The first power transmission gear 244 of the first generator 240 can rotate continuously in one direction to continuously generate power.

The up-and-down motion generator 300 includes: A lifting induction buoyant body 320 slidably connected to an inner wall surface of the lifting tube 310 and having a second power transmission member 350 fixed therein, A weighing spindle 330 connected to the lower end of the induction buoyant body 320 by a connecting rod 332 and made of a weight; vertically downwardly disposed at the upper center of the inner upper portion of the lifting and lowering body 310, The third and fourth driven gears 352 and 352 'are engaged with the both side surface gears 342 and 342' so that the lifting and lowering body 310 moves up and down And a second power transmission member 350 for generating electricity in the second generator 360 by rotational power for rotating the third and fourth driven gears 352 and 352 '.

The lifting and lowering body 310 is fixed to the lower portion of the pivotal motion generating unit 200 and moves up and down together with the buoy body 110. The lifting body 310 has a downwardly- (Not shown) is installed to block the inflow of seawater into the upper portion of the lifting induction buoyant body 320 slidably connected to the lifting tube 310, and at the upper side of the lifting tube 310, It is preferable that the inner space of the lifting induction buoyant body 310 formed to be slidably connected to the lifting tube 310 is formed in a vacuum state so that the lifting tube 310 can be smoothly moved up and down .

The lifting induction buoyant body 320 is formed of a cylinder which is opened upward but the opening portion is positioned inside the slide connection portion of the lifting tube 310 to perform buoyancy function without inflow of seawater, The second power transmission member 350 for generating power from the second generator 360 is installed in the second power transmission member 320 and the third and fourth driven gears 352 and 352 ' The upper and lower kinetic energy of the lifting and lowering body 310 is transmitted to the second power transmission member 350 so that the second generator 360 is generated A hook 322 is formed at the lower part of the outer wall surface of the lifting induction buoyant body 320 and connected to an anchor 400 of the weight installed on the water floor and the support rope 410.

The lifting guide body 320 is slidably connected to the lifting tube 310 and the lifting guide protrusion 311 is formed perpendicularly to the inner wall surface of the lifting tube 310, The lifting guide protrusion 311 of the lifting tube 310 is lifted up and down by the lifting guide groove 321 of the lifting guide buoyancy body 320 So that the vertical movement is performed in the vertical direction.

The weights 330 are provided on the lower ends of the connecting rods 332 perpendicularly connected to the lifting induction buoyant body 320 to induce vertical up and down movement of the lifting and lowering body 310, The lifting induction buoyant body 320 is slidably connected to the lifting body 310 moving up and down together with the buoy body 110, The vertical movement of the lifting and lowering body 310 can be generated by using the vertical movement of the lifting and lowering body 310 by the phase difference generated by making the vertical movement of the lifting body 310 relatively small.

The weights 322 are formed at the lower center of the weights 330 and the anchors 400 of the weights installed on the floor of the weighers are formed. And a supporting rope (410).

The rotation guide boss 340 is fixed to the upper side of the up / down pipe body 310 which vertically moves together with the buoy body 110, And the third and fourth driven gears 352 and 352 'of the second power transmitting member 350 are engaged with the first and second power transmitting members 342 and 342' The third and fourth driven gears 352 and 352 'engaged with the return gears 342 and 342' of the rotation guide guide 340 are converted into rotational kinetic energy to transmit rotational power to the second power transmitting member 350 .

The second power transmitting member 350 includes third and fourth driven gears 352 and 352 'respectively engaged with the both side surface gear teeth 342 and 342', and third and fourth driven gears 352 and 352 ' Third and fourth driven shafts 356 and 356 'provided with four clutch bearings 354 and 354' for selectively generating rotational power, and third and fourth driven shafts 356 and 356 'provided at the other ends of the third and fourth driven shafts 356 and 356' The first and second power transmission gears 368 and 358 'are disposed on both sides of the second power transmission gear 364 provided on the second power generation shaft 362 of the second generator 360, respectively.

The third and fourth driven gears 352 and 352 'are rotated in opposite directions to each other and only one of the third and fourth driven shafts 356 and 356' is rotated by the third and fourth clutch bearings 354 and 354 ' The third driven shaft 356 is rotated by the third clutch bearing 354 during the upward movement of the rotation guide guide rail 340, When the downward movement of the lifting body 310 is performed by means of the fourth clutch bearing 354 'to rotate the fourth driven shaft 356' 340 are converted into rotational kinetic energy to the third and fourth driven gears 352 and 352 'engaged with the return gears 342 and 342' and are alternately transmitted by the second power transmitting member 350 So that the one-way rotational power is always transmitted to the second power generation shaft 362 of the second generator 360 to generate power And so.

In order to facilitate the safe navigation of a ship, the buoy type body 110 of the buoy 100 is provided with power generating means using wave power, and is used as a power source used in the buoy 100. So that it can supply.

That is, when the light guide plate 100 horizontally swings by wave, the horizontal guide rail 216 provided on the upper surface of the swing guide 210, which is a horizontal ring-shaped plate, tilts to one side, The eccentric rotor 220 mounted on the guide rail 216 and rotating in the direction of inclination causes a rotating force to be generated. The eccentric rotor 220 is rotated by a high rotational energy .

The eccentric rotor 220 rotating along the horizontal guide rail 216 continuously rotates in the initial clockwise or counterclockwise direction. The rotational power of the eccentric rotor 220 is transmitted to the eccentric rotor Is transmitted to the center rotary shaft 226 of the first power transmitting member 230 connected to the rotary power transmitting plate 224 of the first and second clutch bearings 220 and 220 so that the first and second driven gears 234 and 234 ' The first power transmission member 230 having the first power generating member 236 and the second power generating member 236 is continuously and unidirectionally connected to the first power generating shaft 242 of the first generator 240 regardless of the rotational direction of the eccentric rotor 220. [ So that the first generator 240 continuously generates electricity.

The lifting tube 310 fixed to the buoy body 110 moves up and down together with the buoy body 110 when the buoy 100 is vertically moved up and down by the wave. The lifting induction buoyant body 320 slidably connected to the lifting body 320 is connected to the lower part and the lifting inducing buoyant body 320 is lifted by the weight 330 composed of a weight body in a phase difference Up and down kinetic energy of the lifting tube 310 converts the third and fourth driven gears 352 and 352 'that are engaged with the return gears 342 and 342' of the rotation inducing guide rod 340 into rotational kinetic energy.

When the third and fourth driven gears 352 and 352 'engaged with the return gears 342 and 342' of the rotation guide bar 340 are continuously rotated by the vertical movement of the lifting tube 310 as described above, The third and fourth clutch bearings 354 and 354 'provided on the third and fourth driven shafts 356 and 356' of the driven gears 352 and 352 'are rotated by the rotational power generated by alternately rotating the second generator The second generator shaft 360 of the second generator 360 is continuously rotated in one direction so that the second generator 360 can continuously generate electricity.

As described above, according to the present invention, there is provided a lighting apparatus comprising a swing motion generating section (200) for making continuous light generation by using the light guide (100) horizontally swinging motion by wave, The vertical movement generating section 300 is provided in the buoy body 110 so that continuous power generation can be performed using the vertical movement generating section 300 and the vertical movement generating section 300, The power generation efficiency of the wave power generation device can be increased.

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

100: light buoy 110: buoy body
120: Structure 200:
The present invention relates to a driving force transmitting mechanism for an internal combustion engine, and more particularly, it relates to an internal combustion engine, First and second driven gears 234 and 235 ': First and second driven gears 236 and 235': First and second driven gears 236 and 236 ': First and second driven gears 238 and 238' A power generator 310, a lifting body 311, an elevating guide protrusion 320, an elevating guide buoyant member 321, an elevating guide groove 322, a hook 330, a weight 332, a connecting rod 340, The transmission members 352 and 352 ': third and fourth driven gears 354 and 354': third and fourth clutch bearings 356 and 356 ': third and fourth driven shafts 358 and 358': third and fourth driven gears 360, : Second power transmission gear 400: anchor 410: support rope

Claims (9)

In light indicators for route guidance,
A swing motion generator 200 installed in the buoy body 110 to perform horizontal swing motion using waves to generate electricity; (300) for generating power by using vertical up and down movement,
A swing guide 210 having a horizontal guide rail 216 on an upper surface thereof in an arc shape and an eccentric rotor 220 installed on the horizontal guide rail 216 and rotating along the horizontal guide rail 216 And a central rotation axis 226 connected to the rotation power transmission plate 224 formed inside the eccentric rotor 220 is installed on the central axis of the swing guide 210 and is transmitted to the central rotation axis 226 And a first power transmitting member (230) generating electric power by a first generator (240) by a rotational power of the first generator (240);
A lifting induction buoyant body 320 slidably connected to an inner wall surface of the lifting tube 310 and having a second power transmission member 350 fixed therein, A weight weight 330 connected to a lower end of the induction buoyant body 320 and a rotation induction guiding member 330 vertically downwardly formed at an inner upper center of the lifting body 310 and having a pair of rack gears 342 and 342 ' The third and fourth driven gears 352 and 352 'are engaged with the both side surface gears 340 and 340 and the third and fourth driven gears 352 and 352' are engaged with the both side surface gears 342 and 342 ' And a second power transmission member (350) generating electric power by a second generator (360) by a rotational power for rotating the second power transmission member (350).
The method according to claim 1,
The swing guide table 210 is fixed to the inside of the buoy body 110 and is provided as a ring shaped plate having a horizontal shape. A horizontal guide rail 216 is provided on the upper surface of the swing guide table 210. Wherein a first power transmitting member (230) including a first generator (240) is installed.
The method according to claim 1,
Wherein the eccentric rotor (220) is provided with a rolling bearing (222) which is provided as a weight and which minimizes frictional resistance with respect to the horizontal guide rail (216).
The method according to claim 1,
The first power transmitting member 230 includes a driving gear 232 provided on the central rotation shaft 226, a first driven gear 234 engaged with the driving gear 232, The first and second driven gears 234 and 234 'are provided with the first and second clutch bearings 236 and 236', and the second driven gear 234 ' The first and second driven shafts 235 and 235 'selectively generate rotational power. The first and second driven shafts 235 and 235' The first power transmission gear 244 is coupled to both sides of the first power transmission gear 244 provided on the first power generation shaft 242 of the first generator 240, So that the rotating power can be transmitted.
The method according to claim 1,
Wherein the lifting and lowering pipe body (310) is fixedly installed at a lower portion of the pivotal motion generating portion (200) and is vertically moved along the buoy body (110).
The method according to claim 1,
The lifting induction buoyant body 320 is formed of a cylinder which is opened upward, and a second power generator 360 generates electric power by the rotational power transmitted from the third and fourth driven gears 352 and 352 ' And a power transmission member (350) is installed on the back surface of the waveguide.
The method according to claim 1,
The weights 330 are provided on the lower ends of the connecting rods 332 perpendicularly connected to the lifting induction buoyant body 320 and the weights 330 can be removed and attached to adjust the weight of the weights 330 Wherein said waveguide waveguide is a waveguide waveguide.
The method according to claim 1,
The rotation guide bands 340 are installed on the lifting and lowering body 310 moving up and down along the buoy body 110 and are connected to the rack gears 342 and 342 'formed on both sides in the longitudinal direction of the rotation guide bands 340 And the third and fourth driven gears (352, 352 ') of the second power transmitting member (350) are engaged with each other.
The method according to claim 1,
The second power transmitting member 350 includes third and fourth driven gears 352 and 352 'respectively engaged with both side surface gear teeth 342 and 342' and third and fourth driven gears 352 and 352 ' Third and fourth driven shafts 356 and 356 'provided with clutch bearings 354 and 354' for selectively generating rotational power and third and fourth driven shafts 356 and 356 'provided at the other ends of the third and fourth driven shafts 356 and 356' 358 and 358 'are installed on both sides of the second power transmission gear 364 provided on the second power generation shaft 362 of the second generator 360.

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