KR102552906B1 - One-way rotational force generating apparatus for wave power generation and wave power generator using them - Google Patents

Abstract

The present invention relates to a one-way rotational force generating device for wave power generation and a wave power generating device using the same.
The wave power generation device according to the present invention includes a frame; a first linear motion unit provided in the frame and linearly reciprocating according to the flow of the frame according to waves; a second linear motion unit provided in the frame; a power transmission unit provided in the frame and connecting the first linear motion unit and the second linear motion unit to transfer the linear reciprocating motion of the first linear motion unit to the second linear motion unit; a one-way rotational force generator provided in the frame to generate rotational force in one direction according to the linear reciprocating motion of the second linear motion unit; And a power generation unit that is connected to the one-way rotational force generating unit and generates energy by the rotational force of the one-way rotational force generating unit.

Description

One-way rotational force generator for wave power generation and wave power generation device using the same

The present invention relates to a one-way rotational force generating device for wave power generation and a wave power generating device using the same.

Recently, electricity is generally produced using petroleum, fossil fuels, and nuclear power, but oil and fossil fuels have limited reserves, so there is a risk of depletion over time. Not only is the period limited, but the disposal of nuclear waste is emerging as a serious problem.

In order to cope with the above-mentioned problem of power generation using petroleum, fossil fuel, and nuclear power, research and development on renewable energy using wind power and solar heat are being actively conducted. Power generation using wind and solar heat has the advantage of virtually unlimited energy sources and less environmental pollution.

However, in the case of power generation using wind power, there is a problem in that it is not easy to find the optimal location because the strength of the wind is very different depending on the season and location. In addition, in the case of solar power generation, the amount of sunlight varies greatly depending on the weather and place, and there is a problem in that the amount of sunlight is limited in the evening and at night. In order to solve this problem, large-scale devices and efficient energy conversion technology are required. The disadvantage is that the production cost is very high.

On the other hand, in recent years, research and development of power generation technologies using wave power among the aforementioned renewable energy have been actively conducted. Wave power generation has the advantage of having relatively few restrictions depending on the season, time, and place for smooth supply and demand of energy sources.

However, wave power generation has a problem in that power generation efficiency is greatly affected by wave height, wave period, and wave direction.

By solving this problem, research and development are being actively conducted to improve the efficiency of wave power generation, but wave power generators according to the prior art have a problem in that power generation efficiency is somewhat lowered during motor control and energy conversion.

US 8487459 B2 KR 10-1212763 B1 KR 10-2230135 B1

An object of the present invention is to solve the above problems, to generate linear reciprocating motion using waves so as to efficiently generate energy using waves, convert the generated linear reciprocating motion into bi-directional rotational motion, and then Its purpose is to provide a one-way rotational force generating device for wave power generation that can efficiently generate energy by converting bidirectional rotational motion into one-way rotational motion and a wave power generation device using the same.

The object of the present invention is not limited to the object mentioned above, and other objects not mentioned will be clearly understood from the description below.

One-way rotational force generating device for wave power generation according to an embodiment of the present invention for achieving the above object is a bracket; a power input unit provided on the bracket and rotating in both directions by power according to waves; and a rotational force output unit provided on the bracket and outputting rotational force generated when the power input unit rotates in both directions.

For achieving the above object, the wave power generation device according to another embodiment of the present invention is a frame; a first linear motion unit provided in the frame and linearly reciprocating according to the flow of the frame according to waves; a second linear motion unit provided in the frame; a power transmission unit provided in the frame and connecting the first linear motion unit and the second linear motion unit to transfer the linear reciprocating motion of the first linear motion unit to the second linear motion unit; a one-way rotational force generator provided in the frame to generate rotational force in one direction according to the linear reciprocating motion of the second linear motion unit; and a power generation unit that is connected to the one-way rotational force generating unit and generates energy by the rotational force of the one-way rotational force generating unit.

In order to achieve the above object according to embodiments of the present invention according to the above configuration, a one-way rotational force generating device for wave power generation and a wave power generation device using the same have the following effects.

Energy can be efficiently generated because the rotational output unit converts not only the one-way rotation of the power input unit by the power according to the waves, but also the rotation in the other direction into one-way rotation to output rotational force.

More specifically, when the first rotational shaft rotates in one direction, the first one-way rotation gear rotates in one direction, and when the first rotation shaft rotates in the other direction, the second one-way rotation gear rotates in one direction, so that both rotations of the input gear rotate in one direction. As the output is output and the generator is driven, more efficient wave power generation can be achieved.

When the frame moves by waves, the first linear motion unit performs linear reciprocating motion, the power transmission unit transmits the linear reciprocating motion of the first linear motion unit to the second linear motion unit, and the linear reciprocating motion of the second linear motion unit is transmitted to the one-way rotational force generating unit. By receiving the transmission, the one-way rotational force generation unit generates rotational force to drive the power generation unit to generate energy.

1 is a perspective view showing a one-way rotational force generating device for wave power generation according to an embodiment of the present invention.
2 is a perspective view showing a wave power generating device according to another embodiment of the present invention.
3 is a side view of a wave power device according to another embodiment of the present invention.
4 is a front view of a wave power generation device for wave power generation according to another embodiment of the present invention.
5 is a perspective view showing a heavy object of a wave power device according to another embodiment of the present invention.
6 is a perspective view showing a power transmission bar of a wave power generation device according to another embodiment of the present invention.

Advantages and features of the present invention, and methods of achieving them, will become clear with reference to the detailed description of the following embodiments taken in conjunction with the accompanying drawings. However, the present invention is not limited to the embodiments disclosed below, but will be implemented in a variety of different forms, only the present embodiments make the disclosure of the present invention complete, and those skilled in the art in the art to which the present invention belongs It is provided to fully inform the person of the scope of the invention. Meanwhile, terms used in this specification are for describing embodiments, and are not intended to limit the present invention. In this specification, singular forms also include plural forms unless specifically stated otherwise in a phrase.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

Wave power generation device according to another embodiment of the present invention includes a one-way rotational force generating device for wave power generation according to an embodiment of the present invention, hereinafter when explaining a wave power generation device according to another embodiment of the present invention The configuration of a one-way rotational force generating device for wave power generation according to an embodiment of the present invention will be described together.

1 to 6, the wave power generating device according to another embodiment of the present invention includes a frame 100, a first linear motion unit 200, a second linear motion unit 400, a power transmission unit 300, the present invention It includes a one-way rotational force generating device 500 and a power generation unit 600 according to an embodiment of.

The frame 100 provides space for the first linear motion unit 200, the power transmission unit 300, the second linear motion unit 400, the one-way rotational force generator 500, and the power generation unit 600 to be provided.

The frame 100 may be placed on a floating body such as a ship floating in the ocean, and may float when the floating body is moved by waves.

The first linear movement unit 200 is provided on the frame 100 and linearly reciprocates according to the movement of the frame 100 according to waves.

The first linear motion unit 200 includes a weight 210 and a guide means 220.

The heavy object 210 linearly reciprocates according to the flow of the frame 100 .

The heavy object 210 may linearly reciprocate in the left and right directions of the frame 100 .

A weight 211 may be detachably provided in the weight 210 so as to adjust the weight of the weight 210 .

The guide means 220 is provided on the frame 100 and guides the linear reciprocating motion of the heavy object 210 .

The guide means 220 connects the frame 100 and the weight 210, and when the frame 100 moves, the weight 210 may slide so as to correspond to the flow of the frame 100.

That is, when the frame 100 moves left and right due to waves, the guide means 220 allows the heavy object 210 to slide in correspondence with the flow of the frame 100, so that the heavy object 210 can reciprocate linearly.

The guide means 220 may include a guide rail 221 provided along one axis of the frame 100 and a guide block 222 provided under the heavy object 210 .

The guide rail 221 may be provided along the left and right directions of the frame 100 and connected to the guide block 222 .

The guide block 222 is fixed to the lower portion of the heavy object 210 and is movably installed along the guide rail 221 so that the heavy object 210 moves linearly on the guide rail 221 according to the inclination of the frame 100. can guide you to do it.

The power transmission unit 300 is provided on both sides of the frame 100 to connect the first linear motion unit 200 and the second linear motion unit 400, and transfers the linear reciprocating motion of the first linear motion unit 200 to the second linear motion unit. It can be transmitted to the exercise unit 400.

The power transmission unit 300 may be composed of a pair of power transmission bars 310 .

In the power transmission bar 310, a center through hole 311 is formed in the center, and the center is rotatably installed on one side and the other side of the frame 100, and each lower end faces one end and the other end of the heavy object 210. It may collide with the heavy object 210 according to the linear reciprocating motion of the heavy object 210.

On both sides of the frame 100, central axes 312 penetrating through the central through hole 311 may be installed along the front and rear directions of the frame 100.

A protruding end 313 protruding in the direction of the heavy object 210 may be formed at the lower end of the power transmission bar 310 so that force due to collision with the heavy object 210 can be effectively transmitted.

The second linear motion unit 400 is provided on the upper part of the frame 100 and receives the linear reciprocating motion of the first linear motion unit 200 from the power transmission unit 300 and performs linear reciprocating motion.

The second linear motion unit 400 may include a linear motion bar 410, a motion transmission piece 420, an elastic recovery unit 430, and a bar 440.

Both ends of the linear movement bar 410 may be supported by a pair of first supports 110 provided on the top of the frame 100 so as to be movable left and right.

The motion transfer pieces 420 are installed to protrude downward at both ends of the linear motion bar 410 and collide with the upper end of the power transmission bar 310 according to the collision between the heavy object 210 and the lower end of the power transmission bar 310 to make a straight line. The movement bar 410 may be linearly reciprocated.

The motion transmission piece 420 may collide with the upper end of the power transmission bar 310 when the lower end of the power transmission bar 310 collides with the heavy object 210, and for this purpose, the motion transmission piece 420 is a linear motion bar ( 410), doedoe, may be provided relatively inner than the power transmission bar 310.

As the motion transmission piece 420 is provided relatively inside than the power transmission bar 310, when the power transmission bar 310 collides with the heavy object 210 and tilts to the inside of the frame 100, the motion transmission piece 420 By colliding with the linear movement bar 410 can be linearly reciprocating.

The elastic recovery unit 430 is installed at both ends of the linear motion bar 410, and exerts an elastic restoring force when the linear motion bar 410 linearly moves so that the linear motion bar 410 can linearly reciprocate.

The elastic recovery unit 430 may include a second support 431 and an elastic member 432 .

The second supports 431 are installed on both sides of the upper portion of the frame 100 and may be spaced apart from each other so as to face both ends of the linear motion bar 410 .

The elastic member 432 connects the second support 431 and the end of the linear motion bar 410 so that when the linear motion bar 410 moves linearly, it is deformed and then elastically restored so that the linear motion bar 410 moves in one direction and the other. It may be to make the linear motion bar 410 linearly reciprocate without linear motion in only one of the directions.

The bar gear 440 is installed along the longitudinal direction of the linear motion bar 410 so as to be located at the center of the upper side of the frame 100, and teeth may be formed in the lower direction of the frame 100.

The one-way rotational force generating device 500 is provided on the frame 100 and generates rotational force in one direction according to the linear reciprocating motion of the second linear motion unit 400 .

The one-way rotational force generating device 500 may include a bracket 510, a power input unit 520, and a rotational force output unit 530.

The bracket 510 may be fixed to the upper central portion of the frame 100 .

The power input unit 520 is provided on the bracket 510 and can rotate in both directions by the linear reciprocating motion of the second linear motion unit 400 .

The power input unit 520 may include first and second rotational shafts 521 and 522 , an input gear 523 , and first and second power transmission gears 524 .

Both ends of the first and second rotation shafts 521 and 522 may be spaced parallel to each other and rotatably installed on the bracket 510 .

The input gear 523 is fixed to the first rotational shaft 521 so as to be engaged with the bar gear 440 located at the upper center of the frame 100 and receives the linear reciprocating motion of the second linear motion unit 400 and receives the first rotational shaft It can rotate in both directions with (521).

When the bar gear 440 is located in the upper center of the frame 100, the linear motion of the linear motion bar 410 is in the input gear 523 even if the linear motion bar 410 moves in either direction of the frame 100. can be communicated effectively.

The first and second power transmission gears 524 are fixed to one end of the first and second rotational shafts 521 and 522 so as to mesh with each other so that the first rotational shaft 521 and the second rotational shaft 522 rotate in opposite directions to each other. can do.

The rotational force output unit 530 is provided on the bracket 510 to output rotational force generated when the power input unit 520 rotates in both directions to the outside.

The rotation force output unit 530 may be composed of first and second one-way rotation gears 531 and 532 , an output shaft 533 and an output gear 534 .

The first and second one-way rotation gears 531 and 532 are connected to the other ends of the first and second rotation shafts 521 and 522 via a one-way bearing 535, respectively, and the first and second rotation shafts 521 and 522 are It can rotate in one direction only when it rotates in one direction.

The one-way bearing 535 is provided between the first and second one-way rotation gears 531 and 532 and the first and second rotation shafts 521 and 522 to control only when the first and second rotation shafts 521 and 522 rotate in one direction. One and two one-way rotation gears (531, 532) may be to rotate in one direction.

The output shaft 533 is provided on the bracket 510 and may be installed in parallel between the first and second rotation shafts 521 and 522 .

The output gear 534 is fixed to the output shaft 533 so that one side is engaged with the first one-way rotation gear 531 and the other side is engaged with the second one-way rotation gear 532, so that the linear reciprocating motion of the second linear motion unit 400 Accordingly, when one of the first and second one-way rotation gears 531 and 532 alternately rotates in one direction, it may rotate in the other direction.

That is, the rotational force output unit 530 may receive the linear reciprocating motion of the second linear motion unit 400 and output one-way rotational force to the outside.

The power generation unit 600 may be connected to the one-way rotational force generating device 500 to generate energy by the rotational force of the one-way rotational force generating device 500 .

The power generation unit 600 may be composed of a generator 610 and an inertia wheel 620.

In the generator 610, the drive shaft 611 is connected to rotate together with the output shaft 533 to generate electrical energy according to the rotation of the output shaft 533.

The inertia wheel 620 is connected to the driving shaft 611 of the generator 610 to make the rotational force transmitted from the one-way rotational force generating device 500 to the generator 610 constant.

Wave power generation device according to another embodiment of the present invention may further include a data providing unit 700.

The data providing unit 700 is provided in the frame 100 to generate an AC voltage according to the linear reciprocating motion of the heavy object 210, and output the intensity and cycle of the generated AC voltage to the outside.

The data providing unit 700 may include a rail gear 710 and a detector 720.

The rail gear 710 may be provided along the left and right longitudinal directions of the heavy object 210 .

The sensor 720 includes a rotational shaft 721 and a sensing gear 722 provided at one end of the rotational shaft 721 to rotate together with the rotational shaft 721 and meshing with the rail gear 710 during rotation, so that the heavy object 210 When the rotating shaft 721 rotates according to the linear reciprocating motion of the , an AC voltage can be generated, and the period and strength of the generated AC voltage can be output to the outside.

The sensor 720 may be connected to a device capable of receiving the period and strength of the AC voltage output to the outside.

When the sensor 720 receives the period and intensity of the AC voltage according to the linear reciprocating motion of the heavy object 210, the wave height and period of the wave can be predicted using this.

In addition, by using the period and strength of the AC voltage output from the sensor 720, the predicted wave height and period and the actual measured wave height and period are compared to determine whether energy is efficiently generated in the power generation unit 600. If the energy generation efficiency is not sufficient in the power generation unit 600, the weight of the heavy object 210 is determined to be light or heavy, and the weight 211 is added to or subtracted from the heavy object 210 to increase the energy of the power generation unit 600. efficiency can be improved.

Those skilled in the art to which the present invention pertains will understand that the present invention can be embodied in other specific forms without changing its technical spirit or essential features. Therefore, the embodiments described above should be understood as illustrative in all respects and not limiting. The scope of the present invention is indicated by the claims to be described later rather than the detailed description above, and all changes or modifications derived from the scope of the claims and equivalent concepts should be construed as being included in the scope of the present invention.

100: frame, 110: first support,
200: first linear motion unit,
210: heavy weight, 211: weight,
220: guide means, 221: guide rail, 222: guide block,
300: power transmission unit, 310: power transmission bar,
311: central through hole, 312: central axis, 313: protruding end,
400: second linear motion unit,
410: linear motion bar, 420: motion transfer piece, 430: elastic recovery unit,
431: second support, 432: elastic member,
440: stick,
500: one-way rotational force generating unit,
510: bracket, 520: power input unit,
521, 522: first and second rotation shafts, 523: input gear, 524, 525: first and second power transmission gears,
530: rotational force output unit,
531, 532: first and second one-way rotation gears, 533: output shaft,
534: output gear, 535: one-way bearing,
600: power generation unit,
610: generator,
611: drive shaft;
620: inertia wheel,
700: data provision unit,
710: rail gear, 720: detector,
721: rotation shaft, 722: sensing gear.

Claims (9)

delete delete delete frame;
a first linear motion unit including a weight that linearly reciprocates according to the flow of the frame, and a guide means provided on the frame to guide the linear reciprocating motion of the weight;
A linear motion bar that linearly reciprocates left and right according to the linear reciprocating motion of the first linear motion unit, and motion transmission pieces provided at both ends of the linear motion bar to linearly reciprocate the linear motion bar according to the collision between the power transmission bar and the weight. And, a pair of supports spaced apart from each other to face both ends of the linear movement bar and installed on both sides of the upper portion of the frame, and connecting the end of the linear movement bar and the support to deform the linear movement bar when it moves linearly An elastic member for allowing the linear motion bar to linearly reciprocate by elastic recovery, provided along the longitudinal direction of the linear motion bar to form saw teeth in the lower direction of the frame, and transfer left and right linear reciprocating motion of the linear motion bar to the input gear. A second linear motion unit including a rod for transmission;
The power transmission bar, the center of which is rotatably installed on one side and the other side of the frame, and each lower end faces one end and the other end of the weight to collide with the weight according to the linear reciprocating motion of the weight; a power transmission unit connecting the first linear motion unit and the second linear motion unit and transmitting the linear reciprocating motion of the first linear motion unit to the second linear motion unit;
A bracket fixed to the frame, first and second rotational shafts spaced apart in parallel from each other and rotatably installed on the bracket at both ends, and fixed to the first rotational shaft to receive left and right linear reciprocating motion of the bar The input gear rotating in both directions together with the first rotational shaft, and fixed to one end of the first and second rotational shafts, respectively, are fixed to be engaged with each other so that the first rotational shaft and the second rotational shaft rotate in opposite directions to each other. 1 and 2 power transmission gears, first and second one-way rotation gears installed to rotate in only one direction at the other ends of the first and second rotation shafts, and an output shaft installed in parallel between the first and second rotation shafts, An output gear fixed to an output shaft, one side of which is meshed with the first one-way rotation gear and the other side of which is meshed with the second one-way rotation gear; which generates rotational force in one direction according to the linear reciprocating motion of the second linear motion unit. Rotational force generating unit; and
A power generation unit that is connected to the one-way rotational force generating unit and generates energy by the rotational force of the one-way rotational force generating unit.
phosphorus wave power generation device. delete delete delete The method of claim 4, wherein the power generation unit
a generator having a driving shaft connected to the one-way rotational force generating unit to generate electric energy by rotating the driving shaft by the rotational force of the one-way rotational force generating unit; and
An inertia wheel connected to the driving shaft of the generator to constant the rotational force transmitted to the generator from the rotational force of the one-way rotational force generating unit.
phosphorus wave power generation device. According to claim 4,
Further comprising a data providing unit provided in the frame and outputting the intensity and period of the AC voltage generated in the linear motion direction of the first linear motion unit to the outside.
phosphorus wave power generation device.

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