JP2014058924A - Energy converting mechanism - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an energy converting mechanism capable of improving energy converting efficiency, and keeping high power generation efficiency to some extent even when water flow and tidal current change.SOLUTION: An energy converting mechanism includes: a vertical shaft water turbine 10; and water flow control means 20 for controlling water flow supplied to the vertical shaft water turbine 10. The water flow control means 20 has a plurality of water flow control plates 21 disposed around the vertical shaft water turbine 10. The water flow control plates 21 are flat plates disposed so that their surfaces 21s are in parallel with a rotating shaft 11 of the vertical shaft water turbine 10. The plurality of water flow control plates 21 are disposed so that gaps 21h respectively formed between adjacent water flow control plates 21, 21, are gradually narrowed toward the vertical shaft water turbine 10. As a flow rate of the water flowing toward the vertical shaft water turbine can be increased with respect to the water flow in a region of the energy converting mechanism 1 by the water flow control means, a rotating speed of the vertical shaft water turbine 10 can be increased, thereby energy converting efficiency can be improved.

Description

  The present invention relates to an energy conversion mechanism. More specifically, the present invention relates to an energy conversion mechanism that can realize good energy conversion efficiency in power generation using tidal currents, ocean currents, waves, and the like.

  In recent years, the use of natural energy has attracted attention as renewable energy. For example, there are solar power generation, wind power generation, geothermal power generation, wave power generation, ocean current power generation, tidal power generation, etc., and some of them have already been put into practical use on a commercial basis, and as valuable power sources It is utilized.

  Of the above renewable energies, solar power generation and wind power generation are easily affected by the weather, and the stability of power generation is always a problem. On the other hand, ocean current power generation and tidal power generation have the advantage that stable power generation can be maintained with little influence from the weather.

  By the way, in power generation using renewable energy, there is a problem that although sunlight, wind, tidal current, and the like have large energy, the efficiency with which the energy can be converted into electric power is low. In order to improve the energy conversion efficiency (power generation efficiency), various developments have been made in ocean current power generation and tidal power generation.

  In ocean current power generation and tidal power generation, a water turbine is used to convert the ocean current or tidal current into electric power. Therefore, in order to improve power generation efficiency, it is important to efficiently rotate the water turbine by the ocean current or tidal current. In particular, in the case of tidal currents, the direction of the water flow may be completely reversed depending on the time. Therefore, even if such a change in the direction of the water flow occurs, a mechanism that can maintain the power generation efficiency to some extent is required.

  In ocean current power generation and tidal power generation, Patent Documents 1 to 3 disclose mechanisms for maintaining power generation efficiency to some extent.

  In the techniques of Patent Documents 1 to 3, a structure having a cylindrical space for passing ocean currents and tidal currents is provided, and a water turbine is disposed inside the cylindrical space of the structure. And it forms so that the internal cross section of cylindrical space may become small toward the part in which the water wheel is provided, and the water flow of the part is made quick.

With this structure, the direction of the water flow flowing in the cylindrical space of the cylindrical structure can be a flow along the axial direction of the cylindrical space. Therefore, power generation efficiency can be improved if a water wheel is arranged in the cylindrical space so as to efficiently rotate with respect to the flow in this direction.
In addition, in the portion where the water wheel is provided, the flow velocity of the water flow is faster than the surrounding water flow and the like, so that the amount of power generation can be increased as compared with the case where the water wheel is arranged as it is in the water flow.

  Moreover, in the technique of patent document 3, the outer surface shape of a structure is made into the shape which spreads toward the edge part from the middle of the axial direction. And in patent document 3, since it is set as this shape, a vortex | eddy_current can be formed in the edge part from which a water flow is discharged | emitted from a cylindrical space by the water | flow current which flows through the outer surface of a structure. There is also a statement that the water flow in the space can be increased.

Japanese Patent No. 4750830 JP 2009-114936 A JP-A-2005-240786

  However, in the techniques of Patent Documents 1 to 3, since the water flow is passed through the cylindrical space of the structure, the axial direction of the cylindrical space coincides with the direction of the water flow or the tidal current in order to improve the power generation efficiency. A structure must be installed. However, the direction of ocean currents and tidal currents is not constant, and the direction changes with time. For this reason, when a structure is installed so as to be suitable for a current or tidal current of a specific time, if the direction of the current or tidal current is changed at other times, the efficiency of power generation is greatly reduced. Therefore, in order to maintain the power generation efficiency in a stable state, the location where the structure is installed should be limited to places where the direction of the ocean current and tidal current does not change much, and the structure can be adapted to the direction of the ocean current and tidal current. To be able to move it.

In the case of tidal currents, the direction of water flow is reversed depending on the state of tides, so the techniques of Patent Documents 1 to 3 adopt a structure that can cope with such changes in tidal currents. ing. Specifically, the structure is structured symmetrically so that the same power generation efficiency can be maintained regardless of which opening flows into the cylindrical space. In other words, even when the direction of the tidal current is reversed by 180 degrees, the structure is formed so that power can be generated with the same power generation efficiency.
However, when the direction of the water flow is reversed, the direction is not necessarily reversed by 180 degrees. Then, even if a structure is installed so that optimum power generation efficiency can be obtained in a situation where a water flow flows from one opening, it is not always possible to generate power with the same efficiency in a situation where a water flow flows from the other opening. Absent.

  As described above, a mechanism has been developed that can improve power generation efficiency in ocean current power generation and tidal power generation, and can maintain power generation efficiency to a certain extent even if the direction of water flow or tidal current changes. However, there is a need for the development of such a mechanism.

  In view of the circumstances described above, an object of the present invention is to provide an energy conversion mechanism that can improve power generation efficiency and can maintain power generation efficiency to a certain degree even if a water flow or a tidal current changes. .

An energy conversion mechanism according to a first aspect of the present invention includes a vertical axis water turbine that rotates in response to a water flow, and a water flow control means that adjusts a water flow supplied to the vertical axis water turbine. A plurality of water flow control plates disposed around the axial water turbine, the water flow control plate is a flat plate disposed so that the surface thereof is parallel to the rotation axis of the vertical axis water turbine, The plurality of water flow control plates are arranged such that gaps formed between adjacent water flow control plates are narrowed toward the vertical axis turbine.
The energy conversion mechanism according to a second aspect of the present invention is the energy conversion mechanism according to the first aspect, wherein the water flow control plate has an inner edge of the water flow control plate and a rotation shaft of the vertical axis turbine in a cross section orthogonal to the rotation axis of the vertical axis turbine. An inner connecting line that connects the outer edge of the water flow control plate and the rotating shaft of the vertical axis turbine is located downstream of the vertical axis turbine in the rotational direction. It is provided.
An energy conversion mechanism of a third invention is characterized in that, in the first or second invention, the plurality of water flow control plates are arranged so as to be rotationally symmetric with respect to a rotation axis of the vertical axis turbine. To do.
According to a fourth aspect of the present invention, there is provided the energy conversion mechanism according to the third aspect, wherein four of the plurality of water flow control plates are provided.
The energy conversion mechanism according to a fifth aspect of the present invention is the first, second, third or fourth aspect of the invention, wherein the water flow control plate is an inner edge of the water flow control plate in a cross section orthogonal to the rotation axis of the vertical axis turbine. And an outer connecting line connecting the outer edge of the water flow control plate and the rotating shaft of the vertical axis turbine is 22.5 to 67. It is arranged to be 5 degrees.
The energy conversion mechanism according to a sixth aspect of the present invention is the energy conversion mechanism according to any one of the first to fifth aspects, wherein the vertical axis turbine and the plurality of water flow control plates are energy conversion sets. The plurality of energy conversion sets are arranged such that the axes of the vertical axis water turbines are parallel to each other.
According to a seventh aspect of the present invention, in the energy conversion mechanism according to any one of the first to sixth aspects, the vertical axis turbine is a Savonius type turbine.

According to the first invention, since the gap formed between the adjacent water flow control plates is arranged so as to narrow toward the vertical axis turbine, the flow rate of the water flow toward the vertical axis turbine by the water flow control means is It can be faster than the water flow in the area where the energy conversion mechanism is installed. For this reason, since the rotational speed of a vertical axis water turbine can be raised, energy conversion efficiency can be made high.
According to the second aspect of the invention, the rotational speed of the vertical axis turbine can be effectively increased by the water flow toward the vertical axis turbine, so that the energy conversion efficiency can be further increased.
According to the third aspect of the invention, a water flow toward the vertical axis turbine can be formed regardless of the direction of the water flow in the region where the energy conversion mechanism is installed. That is, since the power can be generated by rotating the vertical axis turbine regardless of the direction of the water flow in the region where the energy conversion mechanism is installed, the degree of freedom in the location where the energy conversion mechanism is installed can be increased.
According to the fourth invention, since the four water flow control plates are provided at a rotationally symmetric position, the flow velocity of the water flow is effectively improved while maintaining the flow channel of the water flow toward the vertical axis turbine to a certain extent. Can be made. Therefore, the rotation speed of the vertical axis turbine can be effectively increased, and the energy conversion efficiency can be increased.
The energy conversion mechanism according to the fifth aspect of the invention is arranged so that the angle formed by the inner connecting line and the outer connecting line is 22.5 to 67.5 degrees, which is optimal for the rotation of the vertical axis turbine. A water stream can be formed.
The energy conversion mechanism of the sixth aspect of the invention can increase the effect of increasing the flow velocity of the water flow toward each vertical axis turbine due to the influence of the water flow formed by the adjacent energy conversion sets.
According to the seventh aspect of the invention, since the vertical axis turbine is a Savonius type turbine, the rotation efficiency of the turbine due to the water flow between the water flow control plates can be improved, and the energy conversion efficiency can be improved.

It is a schematic external view of the energy conversion mechanism 1 of this embodiment, (A) is a perspective view, (B) is a side view. It is a schematic sectional drawing of the energy conversion mechanism 1 of this embodiment, (A) is a longitudinal cross-sectional view, (B) is a cross-sectional view. It is a schematic explanatory drawing of the cross section of the energy conversion mechanism 1 of this embodiment. It is a schematic explanatory drawing of the energy conversion mechanism 1 of this embodiment which has multiple energy conversion sets. It is the figure which showed the cross section of the apparatus used for experiment, (A) is an apparatus which provided the "K-shaped flow direction control board" used as a comparative example, (B) is the "arc type" used as a comparative example (C) is an apparatus provided with a “vortex flow direction control plate” corresponding to the water flow control plate of the energy conversion mechanism of the present invention. It is the figure which compared the power characteristic in the apparatus from which a water flow control board differs. It is the figure which compared the torque coefficient in the apparatus from which a water flow control board differs. It is the figure which showed the experimental result which measured the load torque and power in the case of changing the angle (theta) of a water flow control board.

  The energy conversion mechanism of the present invention is a mechanism for converting the energy of ocean currents, tidal currents, and waves, and can improve the energy conversion efficiency. Even when water reciprocates in a short cycle, the energy conversion efficiency can be prevented from decreasing.

  The energy conversion mechanism of the present invention is suitable for an energy conversion mechanism of a power generation device that generates power using the energy of the water stream. However, the energy conversion mechanism of the present invention can be used as long as the water turbine can be rotated by the water stream. It is possible to use a mechanism. For example, it can be installed on a fixed structure such as a breakwater or a vertical jetty, or can be mounted on a floating body such as a float, but the installation location is not particularly limited.

Further, when the energy conversion mechanism of the present invention is provided on a breakwater or a longitudinal jetty, an effect of attenuating wave energy can be obtained. For this reason, it can be made to function as a disaster prevention equipment which prevents the disaster by a wave at the time of stormy weather, etc., making it function as a power generation equipment using the energy of the wave by power generation in normal times.
Of course, it goes without saying that the energy conversion mechanism of the present invention may be used simply as a facility for absorbing energy such as waves.

Next, the energy conversion mechanism 1 of the present embodiment will be described based on the drawings.
Hereinafter, a case where the energy conversion mechanism 1 has a function of generating power will be described.

In FIG. 1, the code | symbol 2 has shown the main-body part of the energy conversion mechanism 1 of this embodiment.
The main body 2 includes a pair of frames 3 and 4. The pair of frames 3 and 4 are arranged in a state of being separated from each other so as to form a space 2h through which a water flow can flow. Moreover, the pair of frames 3 and 4 are provided so that a water flow can flow into the space 2h from any direction around the space 2h.

  The opposing surfaces 3a and 4a of the pair of frames 3 and 4 are formed as flat surfaces parallel to each other, but may not be parallel to each other or may not be flat surfaces. However, when the opposing surfaces 3a and 4a of the pair of frames 3 and 4 are flat surfaces parallel to each other, the flow resistance when the reciprocating flow flows between the pair of frames 3 and 4 regardless of the flow direction. The advantage that it can be reduced is obtained.

  As shown in FIGS. 1 and 2, a vertical axis water turbine 10 is provided between the pair of frames 3 and 4 (that is, the space 2 h) of the main body 2. The vertical shaft water turbine 10 includes a pair of plates 13, 13, two rotary blades 12 provided between the pair of plates 13, 13, and a pair of erected on the outer surfaces of the pair of plates 13, 13. Shafts 11 and 11. The pair of shafts 11 and 11 are arranged so as to be coaxial with each other. Hereinafter, an axis passing through the central axis of the pair of shafts 11 and 11 is simply referred to as a rotation axis CL of the vertical axis turbine 10 (see FIG. 2A).

  The vertical shaft water turbine 10 has a pair of shafts 11 and 11 rotatably attached to a pair of frames 3 and 4, respectively. Specifically, in the vertical axis turbine 10, the axial direction of the rotation axis CL intersects (preferably orthogonally) with the direction of the water flow WF (see FIG. 2B) flowing into the space 2h of the main body 2. It is arranged to do.

  Further, the vertical axis water turbine 10 is disposed so as to be located at a substantially central portion of the space 2h. For example, as shown in FIG. 2B, when the cross section of the space 2h is a square, the vertical axis turbine 10 is arranged in the space 2h so that the rotation axis CL passes through the intersection of the diagonal lines DL. Has been.

  In addition, the structure of the vertical axis water turbine 10 is not particularly limited as long as it is rotated by a water flow flowing into the space 2h, and is not particularly limited. However, when a drag type vertical axis turbine is employed as the vertical axis turbine 10, it is preferable to employ a Savonius type turbine as shown in FIGS. Of course, other drag type vertical axis turbines can be used, but when a Savonius turbine is used, the energy conversion efficiency is increased. When the water flow flowing into the space 2h is controlled by the water flow control plate 21 of the water flow control means 20, which will be described later, even if a water flow turbulence occurs near the edge of the water flow control plate 21, the rotation is caused by the influence of the turbulence. This is preferable because problems such as reduction in efficiency are unlikely to occur.

  As shown in FIG. 1, one shaft 11 of the vertical axis water turbine 10 has one end penetrating the frame 3 and connected to power generation means 5 provided in the frame 3. The power generation means 5 has a function capable of generating power by rotating the shaft 11. The power generation means 5 only needs to be capable of generating power by rotating the shaft 11, and various generators such as a known generator can be used.

As shown in FIGS. 1 and 2, a plurality of water flow control plates 21 </ b> A to 21 </ b> D of the water flow control means 20 are provided around the vertical axis turbine 10 between the pair of frames 3 and 4 of the main body 2. ing. These water flow control plates 21 </ b> A to 21 </ b> D are plate-like members having a flat surface, and are provided so that the surface thereof is substantially parallel to the rotation axis CL of the vertical axis turbine 10.
Moreover, as shown to FIG. 2 (B), several water flow control board 21A-21D is arrange | positioned so that it may become rotationally symmetrical with respect to the rotating shaft CL of a vertical axis | shaft water turbine. In addition, a gap 21 h is formed between the adjacent water flow control plates 21 and 21 so as to narrow toward the vertical axis water turbine 10.

  As described above, in the energy conversion mechanism 1 of the present embodiment, the vertical axis water turbine 10 is disposed in the space 2h between the pair of frames 3 and 4 of the main body 2, and the direction of the water flow WF flowing into the space 2h. Thus, the axis of the rotation axis CL of the vertical axis turbine 10 is arranged so as to intersect. Therefore, if the water flow WF flows into the space 2h, the vertical axis turbine 10 can be rotated, so that the power generation means 5 connected to the rotary shaft 11 of the vertical axis turbine 10 can generate electric power.

  Moreover, since the gap 21h is formed between the adjacent water flow control plates 21 and 21 so as to become narrower toward the vertical axis water turbine 10, the water flow in the region where the energy conversion mechanism 1 is installed is arranged. Rather, the flow velocity of the water flow toward the vertical axis turbine 10 can be increased. Then, compared with the case where the water flow control means 20 is not provided, since the rotational speed of the vertical axis water turbine 10 can be increased, the power generation efficiency by the power generation means 5 can be increased.

  Further, the water flow can flow into the space 2h from any direction around it, and the plurality of water flow control plates 21 are also arranged so as to be rotationally symmetric with respect to the rotation axis CL of the vertical axis turbine 10. ing. Then, regardless of the direction of the water flow in the area where the energy conversion mechanism 1 is installed, a water flow with a high flow velocity can be supplied to the vertical axis turbine 10. Since the vertical axis turbine 10 rotates regardless of the direction in which the supplied water flow WF is supplied, no matter how the energy conversion mechanism 1 is installed, if the water flow WF exists around the energy conversion mechanism 1, power generation is performed. can do. That is, since power generation is possible regardless of the state of the water flow WF in the region where the energy conversion mechanism 1 is installed, the degree of freedom in the location where the energy conversion mechanism 1 is installed can be increased.

(Description of water flow control means 20)
As described above, the water flow control plates 21 </ b> A to 21 </ b> D of the water flow control means 20 are arranged such that a gap 21 h that narrows toward the vertical axis turbine 10 is formed between the adjacent water flow control plates 21 and 21. It is installed. There are various methods for disposing the water flow control plate 21 so as to be in such a state, but it is preferable to dispose each water flow control plate 21 as follows.

(About the inclination of the water flow control plate 21)
As shown in FIG. 3, each of the water flow control plates 21 </ b> A to 21 </ b> D is provided such that its surface is inclined with respect to a line La connecting the outer end edge 21 a and the rotary shaft 11 of the vertical axis turbine 10. And each water flow control board 21 is arrange | positioned so that the inner end edge 21b may be located in the downstream of the rotation direction of the vertical axis | shaft water turbine 10 with respect to line La (outer connection line La). That is, the water flow along the surface of each water flow control plate 21 flows so as to generate a force that pushes the rotary blades 12 of the vertical axis turbine 10, and this water flow effectively increases the rotation speed of the vertical axis turbine 10. Can do.

In particular, of the pair of adjacent water flow control plates 21 and 21, the water flow control plate 21 located on the upstream side in the rotation direction of the vertical axis turbine 10 has an inner edge 21 b that connects the rotation shaft 11 of the vertical axis turbine 10. It is preferable that the pair of adjacent water flow control plates 21 and 21 are disposed so as to be located on the downstream side of the surface that bisects the outer edge 21a. For example, in FIG. 3, if it is a pair of water flow control plates 21A and 21B, the inner end edge 21b of the water flow control plate 21A located on the upstream side includes the rotating shaft 11 of the vertical axis turbine 10 and the water flow control plates 21A and 21B. It is preferable that the outer end edge 21a is disposed so as to be located downstream of the surface SF that bisects the outer edge 21a.
In this case, it is possible to reliably prevent the water flow along the surface of each water flow control plate 21 from becoming a flow that hinders the rotation of the vertical axis turbine 10, so that the effect of increasing the rotation speed of the vertical axis turbine 10 by the water flow is achieved. You can definitely get it.

In addition, if the above effects can be obtained, the inclination angle of each water flow control plate 21 with respect to the outer connecting line La is not particularly limited. However, in a cross section orthogonal to the rotation shaft 11 of the vertical axis turbine 10, a line connecting the outer connection line La, the inner end edge 21b of the water flow control plate 21 and the rotation shaft 11 of the vertical axis turbine 10 (inner connection line Lb). It is preferable that the angle [theta] formed by (3) is 22.5 to 67.5 degrees. When the angle θ is 22.5 degrees or less, the ratio of the water flow formed by the water flow control plate 21 to be a water flow that hinders the rotation of the vertical axis turbine 10 is increased. On the other hand, when the angle is 67.5 degrees or more, the water flow control plate 21 becomes resistant to the flow toward the vertical axis turbine 10 and the amount of water that can be supplied to the vertical axis turbine 10 is reduced.
Therefore, the angle θ formed by the inner connecting line Lb and the outer connecting line La is preferably 22.5 to 67.5 degrees, and more preferably 45 ± 10 degrees.

(About the distance between the water flow control plate 21 and the vertical axis turbine 10)
Further, the position where the inner end edge 21b of each water flow control plate 21 is arranged in the radial direction of the vertical axis turbine 10 is not particularly limited as long as it does not contact the rotary blade 21 of the vertical axis turbine 10.

(Number of water flow control plates 21)
The number of the water flow control plates 21 installed around the vertical axis turbine 10 is not particularly limited, but it is preferable to provide at least four water flow control means 20. On the other hand, if the number of water flow control plates 21 is too large, the flow rate of the water flow flowing into the space 2h decreases, so that the energy conversion efficiency decreases. Therefore, the number of water flow control plates 21 installed around the vertical axis turbine 10 is preferably 4 or more, and more preferably 4 to 6.

(About the arrangement of a plurality of water flow control plates 21)
In the above example, the case where the plurality of water flow control plates 21 are installed so as to be rotationally symmetric with respect to the rotation axis CL of the vertical axis turbine 10 has been described, but according to the characteristics of the water flow in the region where the energy conversion mechanism 1 is installed. The posture of each water flow control plate 21 may be changed. For example, when installing in a place where the flow direction does not become the opposite when the flow changes, based on observation of the field situation, each angle is set so that it is at an appropriate angle θ with respect to the water flow in each direction. The posture of the water flow control plate 21 may be adjusted.

(About other functions of the plurality of water flow control plates 21)
As described above, in the energy conversion mechanism 1 of this embodiment, the vertical axis turbine 10 is surrounded by the plurality of water flow control plates 21. The gaps 21 h formed between the plurality of water flow control plates 21 become narrower as they approach the vertical axis turbine 10. In other words, the area in which the region in which the vertical axis turbine 10 is accommodated opens to the outside is small.

  For this reason, even if a drifting object such as driftwood or garbage or a small ship collides with the energy conversion mechanism 1, the drifting object or the like can be prevented from contacting the vertical axis turbine 10. That is, it is possible to reduce the possibility that the vertical axis turbine 10 is damaged due to contact with drifting objects or the like.

  Therefore, even if the energy conversion mechanism 1 of the present embodiment is installed on the seabed or the like, power generation can be stably maintained for a long period of time, and the frequency of maintenance due to damage due to contact with drifting objects can be reduced.

In order to maintain high energy conversion efficiency while installing the energy conversion mechanism 1 of the present embodiment on the seabed or the like to prevent collision with drifting objects and the like, the width of the narrowest part of the gap 21h is the vertical axis turbine 10. A radius of about is desirable.
In order to prevent driftwood or dust from entering the space 2h, it is also effective to provide a net or the like around the energy conversion mechanism 1.

(Parallel type)
Although the energy conversion mechanism 1 of this embodiment may be installed alone, a plurality of energy conversion mechanisms 1 may be installed side by side. That is, when the main body 2, the vertical axis turbine 10, and the water flow control means 20 are energy conversion sets, a plurality of energy conversion sets are set so that the axes 11 of the vertical axis turbine 10 in each energy conversion set are parallel to each other. May be provided. In this case, the effect of increasing the flow velocity of the water flow toward the vertical axis turbine 10 can be increased due to the influence of the water flow formed in the adjacent energy conversion set.
In particular, when the shafts 11 of the vertical axis turbine 10 are arranged in a line, the effect of increasing the flow velocity of the water flow toward the vertical axis turbine 10 can be increased more effectively.

  For example, as shown in FIG. 4, the pair of frames 3 and 4 of the main body 2 are square flat plates, and the base ends of the four water flow control plates 21 are positioned at the vertices of the pair of frames 3 and 4. Consider the case of an energy conversion set in which four water flow control plates 21 are arranged so as to be rotationally symmetric. In this case, it arrange | positions so that the one side of a pair of flame | frames 3 and 4 may contact, and the axis | shaft 11 of the vertical axis | shaft turbine 10 may be located in a line. That is, the energy conversion mechanism 1 in which a plurality of energy conversion sets are arranged is arranged so as to have a substantially rectangular shape in plan view. In this case, in the adjacent energy conversion sets, the base ends of the water flow control plates 21 are connected to each other. The energy conversion mechanism 1 is installed so that the long side of the substantially rectangular shape in plan view faces the water flow. For example, when it is installed on a breakwater, it is installed so that the long side of the substantially rectangular shape in plan view is substantially parallel to the coastline. Then, the water flow flowing into each energy conversion set of the energy conversion mechanism 1 is controlled and accelerated by the water flow control plate 21 located on the side where the water flow flows (that is, the long side of the rectangle) and is supplied to the vertical axis turbine 10. The Moreover, since an adjacent energy conversion set is provided on a side surface parallel to the water flow (that is, a short side having a substantially rectangular shape in plan view), the vertical axis turbine 10 is affected by the influence of the water flow in the adjacent energy conversion set. The effect of accelerating the supplied water flow is higher. Therefore, if the power generation means 5 as described above is provided on the shaft of the vertical axis turbine 10 of each energy conversion set, the power generation efficiency can be further increased.

  We confirmed how the energy conversion efficiency changes by providing water flow control means around the water wheel.

  In the experiment, a device equipped with a water flow control plate around a Savonius-type water wheel was installed in the water channel, a water flow was formed in the water channel, the rotation speed and load torque of the water wheel were measured, and the rotation speed and load torque of the water wheel were measured. Based on the above, the power characteristics and torque coefficient of the turbine were calculated.

As the power characteristics of the water turbine, the flow energy acquisition efficiency was confirmed by examining the change characteristics of the power coefficient Cp with respect to the circumferential speed ratio λ.
Further, the characteristics of the water turbine were confirmed by examining the change characteristics of the torque coefficient Cr with respect to the peripheral speed ratio λ.
The power coefficient Cp, torque coefficient Cr, and peripheral speed ratio λ were calculated based on the following equations.

Power coefficient: Cp = T _t ω / (0.5ρu ³ (2RH))
Torque coefficient: Cr = T _t /(0.5ρu ² (2RH) R)
Peripheral speed ratio: λ = Rω / u

T _t : Load torque measured at time t R: Turbine radius ω: Rotational angular speed of the turbine rotating shaft H: Length of the rotating blade in the rotating shaft direction u: Fluid speed 2 RH: Breakage of the turbine relative to the water flow area

In each experiment, an apparatus having a Savonius type turbine (length H = 300 mm in the rotation axis direction of the rotary blade, diameter 120 mm, outer diameter 70 mm of the rotary blade) was used. And it measured about four types of apparatuses, the apparatus (three types shown in FIG. 5) which installed the water flow control board around the Savonius type | mold water wheel, and the apparatus without a water flow control board.
The apparatus (C) in FIG. 5 is an apparatus in which a “vortex flow direction control plate” corresponding to the water flow control plate of the energy conversion mechanism of the present invention is installed. The apparatus (C) in FIG. 5 has a structure whose cross section is substantially the same as that in FIG. 3, and the water flow control plate is installed so that the angle θ in FIG. 3 is 45 degrees.

  The rotation speed and load torque of the turbine were measured with a torque meter (Tono detector manufactured by Ono Sokki, model number: DP005) attached to the shaft of the turbine. In the measurement, an electromagnetic brake was applied to the load side of the torque meter, and the rotation speed and load torque of the turbine were measured simultaneously.

  The used water channel was a water channel having a width of 500 mm, and water was poured into this water channel so that the water depth h = 0.44 m. In addition, the apparatus was installed in the center of the width direction in a water channel.

The results are shown in FIG. 6 and FIG.
As shown in FIG. 6, regardless of the peripheral speed ratio, a “vortex flow direction control plate” (hereinafter simply referred to as “vortex flow direction control plate”) corresponding to the water flow control plate of the energy conversion mechanism of the present invention was installed. It can be confirmed that the power coefficient of the device is high. Even if the maximum value of the power coefficient in each condition is compared, the device with the “vortex flow direction control plate” is provided with a water flow control plate of another shape about 10 times compared to the case without the water flow control plate. Compared to the case where the water flow energy is about twice or more, it can be confirmed that the water flow energy acquisition efficiency is very high.

  Further, as shown in FIG. 7, regardless of the peripheral speed ratio, it can be confirmed that the torque coefficient of the device provided with the “vortex flow direction control plate” is high. Even when comparing the maximum torque coefficient under each condition, the device installed with the “vortex flow direction control plate” was provided with a water flow control plate of another shape about 8 times compared to the case without the water flow control plate. Compared to the case, it is about twice or more, and it can be confirmed that the characteristics of the water turbine are improved.

  From the above results, since the power coefficient and torque coefficient are increased by installing the water flow control plate as in the energy conversion mechanism of the present invention, the water flow control plate is installed as in the energy conversion mechanism of the present invention. It was confirmed that energy conversion efficiency can be improved by doing so.

  When the water flow control plate was installed as in the energy conversion mechanism of the present invention, the influence of the installation angle of the water flow control plate on the load torque and power was confirmed.

The experiment was performed in the same manner as in Example 1.
In the experiment, in the apparatus (C) of FIG. 5, the angle θ was changed to 0, 22.5, 45, 67.5, and 90 degrees. Note that the length of the water flow control plate is changed along with the change of the angle θ in order to prevent contact between the water flow control plate and the water wheel. The length of the water flow control plate at each angle is 0 degree (90 mm), 22.5 degrees (98 mm), 45 degrees (130 mm), 67.5 degrees (147 mm), and 90 degrees (174 mm).

The results are shown in FIG.
As shown in FIG. 8, when the angle θ is changed, the load torque and the power change, and it was confirmed that the power coefficient and the torque coefficient are the largest under the condition of 45 degrees (that is, the condition of 130 mm). .
In addition, in the case of 22.5 degrees and 67.5 degrees, there was no big difference compared to 45 degrees, whereas in the case of 0 degrees and 90 degrees, the load torque becomes small and the work rate decreases. doing.
From the above results, by changing the angle θ, the load torque and the power change, and if the angle θ is 22.5 to 67.5 degrees, the load torque can be increased and the power can be improved. It was confirmed that it was possible.

  The energy conversion mechanism of the present invention is installed in a fixed structure such as a breakwater or a vertical pier, or is mounted on a floating body such as a float, and the energy conversion mechanism of a power generation apparatus that generates power using the energy of water flow Suitable for

DESCRIPTION OF SYMBOLS 1 Energy conversion mechanism 10 Vertical axis | shaft turbine 20 Water flow control means 21 Water flow control board 21h Crevice CL Rotating shaft Lb Inner connection line La Outer connection line

Claims (7)

A vertical axis turbine that rotates in response to water flow,
Water flow control means for adjusting the water flow supplied to the vertical axis turbine,
The water flow control means
Having a plurality of water flow control plates disposed around the vertical axis turbine,
The water flow control plate
The surface is a flat plate disposed so as to be parallel to the rotation axis of the vertical axis turbine,
The plurality of water flow control plates are:
An energy conversion mechanism characterized in that a gap formed between adjacent water flow control plates is arranged so as to become narrower toward the vertical axis turbine. The water flow control plate is
In a cross section orthogonal to the rotation axis of the vertical axis water turbine, an inner connecting line connecting the inner end edge of the water flow control plate and the rotation axis of the vertical axis water turbine is formed between the outer end edge of the water flow control plate and the vertical axis. An energy conversion mechanism, wherein the energy conversion mechanism is disposed so as to be positioned downstream of the outer connecting line connecting the rotation shaft of the water turbine in the rotation direction of the vertical axis water turbine. The plurality of water flow control plates are:
The energy conversion mechanism according to claim 1, wherein the energy conversion mechanism is arranged so as to be rotationally symmetric with respect to a rotation axis of the vertical axis turbine. 4. The energy conversion mechanism according to claim 3, wherein four of the plurality of water flow control plates are provided. The water flow control plate is
In a cross section orthogonal to the rotation axis of the vertical axis turbine, an inner connection line connecting the inner edge of the water flow control plate and the rotation axis of the vertical axis turbine, the outer edge of the water flow control plate, and the vertical axis turbine The energy conversion according to claim 1, 2, 3 or 4, wherein an angle formed by an outer connecting line connecting to the rotation axis of the shaft is 22.5 to 67.5 degrees. mechanism. When the vertical axis turbine and the plurality of water flow control plates are energy conversion sets, a plurality of the energy conversion sets are provided,
The plurality of energy conversion sets are
6. The energy conversion mechanism according to claim 1, wherein the axes of the vertical axis water turbines are arranged so as to be parallel to each other. The energy conversion mechanism according to claim 1, wherein the vertical axis turbine is a Savonius type turbine.