JP7300590B2 - power generation system - Google Patents

Description

The present invention relates to power generation systems.

2. Description of the Related Art Conventionally, power generators that generate power using an external force have been proposed. Such a power generation device comprises a floating body floating on the water surface of a wave collection groove provided on a jetty, a rod attached to the upper surface of the floating body, a support frame and a support stand provided on the jetty, A support frame and a support stand that support the rod slidably along the vertical direction, and a gear mechanism provided on the jetty, which converts the vertical motion of the rod accompanying the vertical motion of waves into rotational motion in both directions. and a one-piece gear mechanism provided on the jetty for transmitting the rotational motion converted by the gear mechanism to the generator. In addition, the one-tooth gear mechanism includes a plurality of one-tooth teeth, a spring for adjusting the rotation direction of the one-tooth teeth to be the same regardless of the direction of the rotational movement converted by the gear mechanism, and a pin that supports the spring. With such a configuration, it is possible to generate power by driving the generator using the vertical motion of waves introduced into the wave collecting groove.

JP-A-58-008271

However, in the above-described conventional power generator, as described above, the single gear of the single gear mechanism has a special configuration including a plurality of single teeth, a spring, and a pin. Since gears cannot be used, there is room for improvement in terms of manufacturability and manufacturing costs.

The present invention has been made in view of the above, and an object of the present invention is to provide a power generation system capable of improving manufacturability and reducing manufacturing costs.

In order to solve the above-mentioned problems and achieve the object, the power generation system according to claim 1 is a power generation system that converts external force into electricity through power generation means, at least a part of which can float on the water surface. a floating body portion that has a space inside the floating body portion and receives a component of the external force in a specific direction; The power generation means having a rotating shaft that rotates only in the power generation rotation direction, which is the rotation direction, and the rotational force conversion means accommodated in the floating body portion, which converts the external force into a rotational force in the power generation rotation direction, and a rotational force conversion means for transmitting the converted rotational force to the power generation means, wherein the rotational force conversion means is a spring portion connected to the floating body portion, and the external force received by the floating body portion. a spring portion that can convert the external force into a rotational force in the power generation rotation direction as the spring portion expands and contracts due to a component force in a specific direction of; and a transmission means connected to the spring portion, a transmission means for transmitting the rotational force to the power generation means by rotationally moving itself while creating a phase difference between the swing of the floating body portion and the swing of the transmission means due to the weight of the transmission means; pressing means connected to the floating body portion for pressing the transmission means so that the transmission means can be rotated in accordance with the expansion and contraction of the spring portion; The spring portion was arranged outside the pressing means, and the spring portion and the pressing means were arranged side by side along the extension/contraction direction of the spring portion.

Further, the power generation system according to claim 2 is the power generation system according to claim 1 , wherein the component force of the external force in the specific direction is a component force in the vertical direction of the external force, and one of the ends of the floating body is connected to one of the ends in the vertical direction, and the other of the ends of the spring portion in the expansion and contraction direction is connected to the transmission means; one end of the pressing means is connected to the other end of the floating body in the vertical direction so that the transmission means can swing in a substantially vertical direction as it expands and contracts; A plurality of sets each including the spring portion, the transmission means, the pressing means, and the power generation means are accommodated in the floating body portion, and the expansion and contraction directions of the spring portions in some of the plurality of sets, and The expansion and contraction directions of the spring portions in the other part of the groups are made different from each other.

According to the power generation system of claim 1, since it is not necessary to configure the power generation system with a special structure, it is possible to improve the manufacturability of the power generation system and reduce the manufacturing cost.

1 is a schematic diagram showing a power generation system according to Embodiment 1 of the present invention; FIG. FIG. 2 is an enlarged perspective view showing peripheral regions of a first transmission portion and a second transmission portion of FIG. 1; FIG. 3 is a cross-sectional view taken along the line AA of FIG. 2; It is a perspective view which shows the front side part of an accommodating part. FIG. 11 is a perspective view showing a state in which the pressing portion has moved relatively linearly upward and backward with respect to the first transmission portion and the second transmission portion; FIG. 11 is a perspective view showing a state in which the pressing portion has moved relatively linearly forward and downward with respect to the first transmission portion and the second transmission portion; FIG. 4A is a perspective view showing a state in which the receiving portion has moved relatively linearly, in which (a) is a view showing the state in which the receiving portion has moved relatively linearly upward and backward, and (b) is a view showing the state in which the receiving portion has moved forward. It is a figure which shows the state which carried out the relative linear movement toward the downward diagonal direction. FIG. 2 is a diagram showing a modification of the power generation system according to Embodiment 1; FIG. FIG. 2 is a diagram showing a modification of the power generation system according to Embodiment 1; FIG. FIG. 2 is a diagram showing a modification of the power generation system according to Embodiment 1; FIG. FIG. 2 is a diagram showing a modification of the power generation system according to Embodiment 1; FIG. FIG. 2 is a diagram showing a modification of the power generation system according to Embodiment 1; FIG. FIG. 2 is a diagram showing a modification of the power generation system according to Embodiment 1; FIG. FIG. 5 is a diagram showing a modification of the housing portion according to Embodiment 1; FIG. 3 is an enlarged right side view showing the power generation system according to Embodiment 2, and is a diagram showing a region corresponding to FIG. 2; FIG. 11 is a right side view showing a state in which the pressing portion has moved relatively linearly upward and backward with respect to the transmitting portion; FIG. 10 is a right side view showing a state in which the pressing portion has moved relatively linearly forward and downward with respect to the transmitting portion; FIG. 11 is a schematic diagram showing a power generation system according to Embodiment 3; FIG. 10 is a diagram showing a modification of the power generation system according to Embodiment 3; FIG. 11 is a schematic diagram showing a power generation system according to Embodiment 4; FIG. 12 is a diagram showing a modification of the power generation system according to Embodiment 4; FIG. 12 is a diagram showing a modification of the power generation system according to Embodiment 4; FIG. 12 is a diagram showing a modification of the power generation system according to Embodiment 4; FIG. 12 is a diagram showing a modification of the power generation system according to Embodiment 4; FIG. 11 is a schematic diagram showing a power generation system according to Embodiment 5; FIG. 12 is a diagram showing a modification of the power generation system according to Embodiment 5; FIG. 12 is a diagram showing a modification of the power generation system according to Embodiment 5; FIG. 12 is a diagram showing a modification of the power generation system according to Embodiment 5; FIG. 12 is a diagram showing a modification of the power generation system according to Embodiment 5; FIG. 11 is a schematic diagram showing a power generation system according to Embodiment 6; FIG. 12 is a diagram showing a modification of the power generation system according to Embodiment 6; FIG. 12 is a diagram showing a modification of the power generation system according to Embodiment 6; FIG. 12 is a diagram showing a modification of the power generation system according to Embodiment 6; FIG. 12 is a diagram showing a modification of the power generation system according to Embodiment 6; FIG. 12 is a diagram showing a modification of the power generation system according to Embodiment 6;

Embodiments of a receiving device according to the present invention will be described in detail below with reference to the accompanying drawings. First, [I] the basic concept of the embodiment will be explained, then [II] the specific contents of the embodiment will be explained, and finally [III] modifications of the embodiment will be explained. However, the present invention is not limited by the embodiment.

[I] Basic concept of the embodiment First, the basic concept of the embodiment will be described. Embodiments generally relate to a power generation system that converts an external force into electricity via power generation means.

Here, "external force" is a concept including, for example, wave power, wind power, human power, mechanical power, etc., but in the embodiment, it will be explained as wave power. Also, the "power generation means" is a concept that converts an external force into electricity and includes, for example, a dynamo. In addition, although the power generation system can be installed on any target, for example, breakwaters, seawalls, quays, piers, offshore, and the like are applicable. In the following embodiments, a case will be described in which the power generation system is a power generation system that converts the wave power of waves generated in the sea into electricity via a dynamo.

[II] Specific contents of the embodiment Next, specific contents of the embodiment will be described.

[Embodiment 1]
First, Embodiment 1 will be described. This form is a form which generates electric power using the horizontal component of wave force.

(composition)
First, the configuration of the power generation system according to Embodiment 1 will be described. FIG. 1 is a schematic diagram showing a power generation system according to Embodiment 1 of the present invention. FIG. 2 is an enlarged perspective view showing a peripheral region of the first transmission section and the second transmission section of FIG. 1; 3 is a cross-sectional view taken along line AA of FIG. 2. FIG. In the following explanation, the X direction in FIG. 1 is the front-back direction of the power generation system (+X direction is the front direction of the power generation system (offshore direction), -X direction is the rearward direction of the power generation system (land side direction)). , the Y direction in FIG. 2 is the horizontal direction of the power generation system (-Y direction is the left direction of the power generation system, +Y direction is the right direction of the power generation system), the Z direction in FIG. 1 is the vertical direction of the power generation system (+Z direction is the power generation system The upward direction of , and the -Z direction is called the downward direction of the power generation system. The power generation system 1 is a system that converts an external force into electricity via a dynamo of a power generation section 80, which will be described later. As shown in FIGS. 1 to 3, the power generation system 1 includes a housing portion 10, a pressing portion 20, a first transmission portion 30a (first transmission means), a second transmission portion 30b (second transmission means), a first A shaft 50 , a belt 60 , a second shaft 70 and a power generation section 80 are provided.

(Construction-Container)
The housing portion 10 is housing means for housing at least a receiving portion 22 to be described later. The accommodating portion 10 is a long, substantially annular body made of, for example, rustproof steel (that is, openings 13 are formed at the front and rear ends of the accommodating portion 10). ), specifically, as shown in FIG. It is formed in a shape and size that can be accommodated. In addition, as shown in FIG. 1, the accommodation portion 10 is arranged at a position where waves can flow in and out of the interior of the accommodation portion 10, and is fixed to the breakwater (installation target) by a fixture or the like. . The details of the configuration of this housing portion 10 will be described later.

(Construction - pressing part)
The pressing portion 20 is pressing means for pressing the first transmission portion 30a and the second transmission portion 30b so that the first transmission portion 30a and the second transmission portion 30b can be rotated. The pressing portion 20 is an elongated body made of, for example, rustproof steel, and as shown in FIGS. installed in position. The details of the configuration of the pressing portion 20 will be described later.

(Construction-first transmission section, second transmission section)
The first transmission portion 30a and the second transmission portion 30b are transmission means for transmitting a rotational force in the rotation direction of power generation, which will be described later, to the dynamo of the power generation portion 80, which will be described later, by rotating themselves. These first transmission portion 30a and second transmission portion 30b have, for example, a plurality of protrusions 40, and are known ratchet gears (in Embodiment 1, the first A ratchet gear or the like that allows the rotational speeds of the transmission portion 30a and the second transmission portion 30b to be approximately the same, and as shown in FIGS. They are arranged side by side and fixed to the first shaft 50 by fixtures or the like.

(Configuration - 1st shaft)
The first shaft 50 is for transmitting the rotational force transmitted from the first transmission portion 30 a or the second transmission portion 30 b to the belt 60 . As shown in FIGS. 1 and 2, the first shaft 50 is a substantially elongated rod-shaped body made of, for example, rustproof steel. are installed along. In addition, the first shaft 50 may be fixed by any method, but for example, fixtures (for example, ball bearings, etc.) capable of rotating both ends of the first shaft 50 in the longitudinal direction with respect to the housing portion 10 may be used. ).

(Configuration - Belt)
The belt 60 is for transmitting the rotational force transmitted from the first shaft 50 to the second shaft 70 . As shown in FIG. 1, the belt 60 is configured using, for example, a known endless belt, and the longitudinal direction of the belt 60 is the direction from the first shaft 50 to the second shaft 70 (in FIG. 1, and the inner peripheral surface of the belt 60 and the outer peripheral surfaces of the first shaft 50 and the second shaft 70 are in contact with each other.

(Configuration - 2nd shaft)
The second shaft 70 is for transmitting the rotational force transmitted from the belt 60 to the dynamo of the power generating section 80, which will be described later. As shown in FIG. 1, the second shaft 70 is a substantially elongated rod-shaped body made of, for example, rustproof steel. , and a position on the land side of the second transmission portion 30b, the longitudinal direction of the second shaft 70 is installed along the left-right direction. The second shaft 70 may be fixed by any method, but for example, a portion of the second shaft 70 may be inserted through an insertion hole (not shown) formed in the side wall of the housing 81 of the power generation unit 80, which will be described later. and is housed inside the housing 81, and the housed part is fixed to the rotating shaft of the dynamo by a fixture or the like. The pressing portion 20, the first transmission portion 30a, the second transmission portion 30b, the first shaft 50, the belt 60, and the second shaft 70 correspond to "rotational force conversion means" in the scope of claims.

(Configuration - power generation section)
The power generation section 80 is for generating power using the rotational force transmitted from the first transmission section 30a or the second transmission section 30b via the first shaft 50, the belt 60, and the second shaft 70. . As shown in FIG. 1, the power generation section 80 is installed at substantially the same position as the second shaft 70, and includes a housing 81, a dynamo (not shown), and a circuit board (not shown). The housing 81 is protective means for protecting the dynamo and the circuit board, and is a substantially box-shaped body made of, for example, a resin material, and having one side surface (eg, the upper surface, etc.) that can be freely opened and closed. , and is fixed to the housing portion 10 by a fixture or the like. The dynamo is a power generating means that generates power by rotating a rotating shaft (not shown) of the dynamo due to a rotational force transmitted through the second shaft 70 . For this dynamo, for example, the rotating direction in which the rotating shaft of the dynamo can generate power (for example, the clockwise rotating direction when viewed from the right direction) is the rotating direction in which power can be generated. is referred to as the “power generation rotation direction”), and is fixed to the housing 81 by fixtures or the like. A substrate on which an electric circuit (not shown) for realizing various functions of the power generation system 1 is mounted. ing. In addition, a power conversion section and a power output section are mounted on this circuit board (both are not shown). Among them, the power conversion unit is power conversion means for converting power generated by the dynamo into predetermined power, and is electrically connected to the dynamo via wiring (not shown). The power output unit is power output means for outputting the power converted by the power conversion unit to an external device (not shown), and is electrically connected to the external device via wiring (not shown). ing.

(Configuration - details of the configuration of the containment section)
Next, the details of the configuration of the housing portion 10 will be described. FIG. 4 is a perspective view showing the front portion of the housing portion 10. As shown in FIG. In Embodiment 1, as shown in FIG. 4 , the accommodation portion 10 includes a first accommodation portion 11 and a second accommodation portion 12 .

The first accommodation portion 11 is a portion that accommodates a portion of the pressing portion 20 (specifically, a receiving portion 22 and the like, which will be described later), and as shown in FIG. A part of the front part is installed so that it is always located in the water. The second accommodation portion 12 is a portion that accommodates another portion of the pressing portion 20 (specifically, a body portion 21 and the like described later), the first transmission portion 30a, the second transmission portion 30b, and the power generation portion 80. , located on the land (breakwater) and connected to the first containment portion 11, as shown in FIG. Further, although the details of the internal shape of each of the first housing portion 11 and the second housing portion 12 are arbitrary, in the first embodiment, the inside of the housing portion 10 is distorted by the waves flowing into the housing portion 10 . By amplifying the water level, it is formed in a shape capable of promoting relative linear movement of the pressing portion 20, which will be described later. Specifically, regarding the internal shape of the first housing portion 11, as shown in FIG. It is formed in an annular shape (specifically, an ellipsoidal shape longer than the vertical length of the inner diameter of the first housing portion 11) in which the length in the left-right direction increases from the land side to the offshore side. . Regarding the internal shape of the second housing portion 12, the length of the inner diameter in the left-right direction and the length in the up-down direction do not change from the land side to the offshore side. It is formed in an ellipsoidal shape that is substantially the same as the inner diameter of the land-side end of the 1 accommodation portion 11 . With such a shape, when waves flow into the interior of the accommodation portion 10, the inside of the accommodation portion 10 is more likely to be affected than when the internal shapes of the first accommodation portion 11 and the second accommodation portion 12 are made uniform. The water level can be amplified, and the internal water level of the accommodation part 10 can be rapidly lowered when the inflowing waves flow out of the accommodation part 10 . Therefore, relative linear movement of the pressing portion 20, which will be described later, can be effectively performed, and the power generation amount of the power generation system 1 can be increased. However, the internal shape of each of the first housing portion 11 and the second housing portion 12 is not limited to the shape described above. , the relative linear movement of the pressing portion 20, which will be described later, may not be promoted.

(Structure-details of the structure of the pressing portion)
Next, the details of the configuration of the pressing portion 20 will be described. FIG. 5 is a perspective view showing a state in which the pressing portion 20 is linearly moved relative to the first transmission portion 30a and the second transmission portion 30b toward the upper rearward oblique direction, which will be described later. FIG. 6 is a perspective view showing a state in which the pressing portion 20 is linearly moved relative to the first transmission portion 30a and the second transmission portion 30b in a forward and downward oblique direction, which will be described later. 7A and 7B are perspective views showing a state in which the receiving portion 22 described later has undergone relative linear movement, and FIG. (b) is a diagram showing a state in which a receiving portion 22, which will be described later, has undergone relative linear movement, which will be described later, in a forward and downward oblique direction. In Embodiment 1, as shown in FIG. 1, the pressing portion 20 includes a body portion 21, a receiving portion 22, and a connecting portion 23. As shown in FIG.

(Structure-details of the structure of the pressing portion-main body portion)
The body portion 21 is the basic structure of the pressing portion 20 . As shown in FIGS. 1 to 3, the body portion 21 is formed by combining a plurality of long frame portions so that the side surface thereof has a relatively thick, substantially annular shape. Specifically, the plurality of frame portions include a first frame portion 21a arranged on the side of the first transmission portion 30a and a second frame portion 21a arranged so as not to face the first frame portion 21a on the side of the second transmission portion 30b. A frame portion 21b, a third frame portion 21c connecting the front portion of the first frame portion 21a and the front portion of the second frame portion 21b, and the rear portion of the first frame portion 21a and the rear portion of the second frame portion 21b. It is composed of a fourth frame portion 21d connecting the side portion.

Further, as for the details of the shapes of the first frame portion 21a and the second frame portion 21b, in Embodiment 1, the rotation center axis (first shaft 50) around which the first transmission portion 30a or the second transmission portion 30b rotates is A wave force acts on the pressing portion 20 within a perpendicular virtual plane (in FIG. 1, an XZ plane that is virtually generated in the internal space of the main body 21 is defined as a virtual plane; hereinafter referred to as a “virtual plane”). (external force), the pressing portion 20 moves linearly relative to the first transmission portion 30a and the second transmission portion 30b along a virtual plane (specifically, a virtual Relative linear movement substantially along the longitudinal direction of the surface (front, back, up, down, oblique directions; hereinafter referred to as "relative linear movement"), it is possible to secure a predetermined amount of movement (so-called stroke). formed into a shape. Here, the "predetermined movement amount" is set to a movement amount that allows the dynamo to generate a desired amount of power generation by relative linear movement of the pressing portion 20, for example. Specifically, the first frame portion 21a has a substantially inverted U-shaped side surface. The length in the direction (substantially in the front-rear direction) is longer than the circumference of the first transmission portion 30a (for example, the length is an integral multiple (or a multiple other than an integral multiple) of the circumference of the first transmission portion 30a). The length in the lateral direction (substantially vertical direction) of the internal space partly surrounded by the 1 frame portion 21a is formed to be substantially the same as the vertical direction length of the first transmission portion 30a. In addition, the second frame portion 21b is formed to have a substantially U-shaped side surface. (approximately in the front-rear direction) is longer than the length of the circumference of the second transmission portion 30b (for example, the length of an integral multiple (or a multiple other than an integral multiple) of the circumference of the second transmission portion 30b, etc.). The length in the lateral direction (substantially vertical direction) of the inner space partially surrounded by the two frame portions 21b is formed to be substantially the same as the vertical length of the second transmission portion 30b. However, the invention is not limited to this. (The same applies to the second frame portion 21b).

Further, as shown in FIGS. 2 and 3, a first toothed portion 24 is provided on the first frame portion 21a, and a second toothed portion 25 is provided on the second frame portion 21b. The first tooth portion 24 is for pressing the first transmission portion 30a and has a plurality of protrusions 26 . Further, as shown in FIG. 2, the first tooth portion 24 is arranged so as to be able to contact with the first transmission portion 30a. It is arranged along the moving direction of the relative linear movement of the pressing part 20 at the end on the 30a side (that is, the lower end of the horizontal bar portion). The second tooth portion 25 is for pressing the second transmission portion 30b and has a plurality of protrusions 26 . Further, as shown in FIG. 2, the second tooth portion 25 is arranged so as to be able to contact with the second transmission portion 30b. 30b side end (that is, the upper end of the horizontal bar portion) (that is, at a position spaced apart from the first tooth 24) is arranged along the moving direction of the relative linear movement of the pressing portion 20. It is

Further, the shape of the protrusion 26 in each of the first tooth 24 and the second tooth 25 is arbitrary, but in the first embodiment, the pressing part 20 is inclined upward (specifically, backward and upward). diagonal direction), the first transmission portion 30a is pressed by the first tooth portion 24 to rotate in the power generation rotation direction, and the pressing portion 20 moves downward in an oblique direction (specifically, When the second transmission portion 30b is pressed by the second tooth portion 25, the second transmission portion 30b is pressed by the second tooth portion 25 to rotate in the power generation rotation direction. Specifically, as for the shape of the protrusion 26 of the first tooth portion 24, as shown in FIG. 6, the protrusion 26 of the first tooth 24 and the protrusion 40 of the first transmission part 30a mesh with each other, so that the first transmission part 30a is pressed by the first tooth 24. However, as shown in FIG. 2, when the pressing portion 20 moves forward and downward with respect to the first transmission portion 30a and the second transmission portion 30b, the projection portion 26 of the first tooth portion 24 and the first transmission portion 30a The projection 26 of the first tooth 24 protrudes downward and rearward so that the first transmission part 30a is not pressed by the first tooth 24 by not meshing with the projection 40 of the first tooth 24. is formed in As for the shape of the protrusion 26 of the second tooth portion 25, as shown in FIG. 6, although the projection 26 of the second tooth 25 and the projection 40 of the second transmission part 30b do not mesh with each other, the second transmission part 30b is not pressed by the second tooth 25. However, as shown in FIG. Furthermore, when the pressing portion 20 moves forward and downward with respect to the first transmission portion 30a and the second transmission portion 30b, the projection portion 26 of the second tooth portion 25 and the projection portion of the second transmission portion 30b 40, the projection 26 of the second tooth 25 is formed in such a shape as to protrude forward and upward so that the second transmission part 30b is pressed by the second tooth 25. there is With such a shape, when the pressing portion 20 moves relatively linearly, the pressing portion 20 causes either the first transmission portion 30a or the second transmission portion 30b regardless of the moving direction of the relative linear movement. It can be pressed so as to rotate in the direction of power generation rotation. Therefore, compared to the case where the protruding portions 26 of the first tooth portion 24 and the second tooth portion 25 have a shape that protrudes with an inclination toward the upper front side (or the lower rear side), the above-described relative linear movement is reduced. In the case of movement in one movement direction, it is possible to avoid the inability to generate power due to the first transmission portion 30a and the second transmission portion 30b not being pressed by the first tooth portion 24 or the second tooth portion 25. , it is possible to reliably generate power.

(Structure-details of structure of pressing part-receiving part)
The receiving part 22 receives a horizontal component force of wave force, and as shown in FIGS. , and is installed so as to be positioned below the body portion 21 . Further, although the specific configuration of the receiving portion 22 is arbitrary, in the first embodiment, as shown in FIG. ), the wave water flows into the inside of the receiving portion 22, and as shown in FIG. It is formed so that the water that has flowed in flows out to the outside of the receiving portion 22 when the relative linear movement is performed. Specifically, first, as shown in FIGS. 1 and 7, the front portion of the receiving portion 22 is formed in a recessed shape protruding rearward. As a result, the amount of inflow and outflow of wave water in the receiving portion 22 can be increased. Further, as shown in FIGS. 1 and 7, the lower end of the front portion of the receiving portion 22 is provided with a return portion 22a that protrudes upward from the lower end, so that the pressing portion 20 is inclined forward and downward. It is possible to suppress part of the water that has flowed into the receiving portion 22 from flowing out when the water is relatively linearly moved in the direction. With such a receiving portion 22, the weight of the water that has flowed into the receiving portion 22 allows the pressing portion 20 to be relatively linearly moved downward (specifically, in a forward and downward oblique direction). Compared to the case where the receiving portion 22 is formed so that wave water does not flow into the inside of the portion 22, the pressing portion 20 can be relatively linearly moved more reliably.

Further, as shown in FIGS. 1 and 7, a moving portion 22b is provided at the lower end portion of the receiving portion 22. As shown in FIGS. The moving part 22b is a moving means for moving the pressing part 20 using the horizontal component force of the wave force. The moving portion 22b is configured using a known roller member such as a wheel member, and is fixed to the receiving portion 22 by a rotatable fixture or the like.

(Structure-details of structure of pressing part-connection part)
The connection portion 23 connects the body portion 21 and the receiving portion 22 . As shown in FIG. 1, the connecting portion 23 is formed of an elongated substantially rod-like body, and is disposed between the main body portion 21 and the receiving portion 22. The front end portion of the connecting portion 23 is the receiving portion. 22 by welding or the like, and the rear end portion of the connecting portion 23 is connected to the main body portion 21 by welding or the like.

(Configuration-details of installation positions of the pressing portion, the first transmission portion, and the second transmission portion)
Next, installation positions of the pressing portion 20, the first transmission portion 30a, and the second transmission portion 30b will be described. Regarding the details of the installation positions of the pressing portion 20, the first transmission portion 30a, and the second transmission portion 30b, in Embodiment 1, as shown in FIG. is applied to the receiving portion 22, the pressing portion 20 is relatively linearly moved in an upward oblique direction (specifically, in a rearward and upward oblique direction). is pressed and rotationally moved, and as shown in FIG. When the pressing portion 20 moves in a diagonally downward direction (specifically, in a diagonally forward and downward direction) as the weight of the portion 20 drops, the body portion 21 presses the second transmission portion 30b. The pressing portion 20, the first transmission portion 30a, and the second transmission portion 30b are installed so as to rotate with each other. Specifically, as shown in FIG. 2, when the first transmission portion 30a and the second transmission portion 30b are housed along the virtual plane in the internal space of the main body portion 21, the protrusion of the first transmission portion 30a The projection 40 of the second transmission part 30b and the projection 26 of the second tooth 25 are installed so that they can come into contact with each other. It is installed so that As for the state of contact between the first transmission portion 30a and the first tooth portion 24, the first transmission portion 30a can be pressed by the first tooth portion 24 and rotated by the relative linear movement of the pressing portion 20. As for the contact state between the second transmission portion 30b and the second tooth portion 25, the second transmission portion 30b is moved by the second tooth portion 25 by the relative linear movement of the pressing portion 20. It is in contact so that it can be pressed and rotated. Due to such an installation position, when the pressing part 20 moves relatively linearly upward and downward, power can be generated using the wave force and the weight of the pressing part 20, so that only the wave force can be used. Compared to the case of generating power, it is possible to reliably generate power in the power generation system 1 regardless of the moving direction of the relative linear movement. In such an installation position, the first transmission portion 30a and the second transmission portion 30b may drop off from the pressing portion 20 to the left or right. A drop-off preventing portion (not shown) may be provided on the first transmission portion 30a and the second transmission portion 30b (or the pressing portion 20).

Due to the structure of the power generation system 1 as described above, the first transmission part 30a and the second transmission part 30b can be configured with commercially available parts (for example, ratchet gears, etc.). Since it is not necessary to do so, it is possible to improve the manufacturability of the power generation system 1 and reduce the manufacturing cost. In particular, even when the power generation system 1 is installed on land (breakwater), it is possible to obtain the horizontal component force necessary for power generation, and to use the horizontal component force to generate a desired amount of power generation. can. Therefore, compared to the case of installing the power generation system 1 offshore, installation work of the power generation system 1 (for example, installation of the power generation system 1) can be performed while avoiding obstruction of the use of the water area used for fishing grounds and ship routes. It is possible to reduce the labor involved in the work of installing an electric cable that connects the power generation unit 80 and an external device (eg, a power storage unit, etc.) provided on land.

(Configuration - function of power generation system)
The functions of the power generation system 1 configured in this way will be described.

First, for example, as shown in FIG. 5, when the horizontal component force of the wave is applied to the receiving portion 22 within the plane of the virtual plane, the pressing portion 20 moves relatively linearly upward and backward. do. In this case, the first transmission portion 30a is pressed by the first tooth portion 24 of the pressing portion 20 and rotationally moves in the power generation rotation direction (clockwise rotation direction), whereby the first transmission portion 30a and the first tooth The portion 24 converts the horizontal force component into a rotational force in the power generation rotation direction (clockwise rotation direction). Then, the converted rotational force in the power generation rotation direction (clockwise rotation direction) is transmitted through the first shaft 50, the belt 60, and the second shaft 70 to the rotation axis of the dynamo in the power generation section 80 by the first transmission section 30a. When the power is transmitted to the dynamo, the rotating shaft of the dynamo rotates due to the transmitted rotational force, so that the dynamo can generate power.

Further, for example, as shown in FIG. 6, when the horizontal component force is no longer applied to the receiving portion 22 after the pressing portion 20 has relatively linearly moved upward and backward, the pressing portion 20 is The pressing portion 20 relatively linearly moves forward and downward along with the drop of its own weight. In this case, the second transmission portion 30b is pressed by the second tooth portion 25 of the pressing portion 20 and rotationally moves in the power generation rotation direction (clockwise rotation direction). The portion 25 converts the self-gravity of the pressing portion 20 into a rotational force in the power generation rotation direction (clockwise rotation direction). Then, the converted rotational force in the power generation rotation direction (clockwise rotation direction) is transmitted through the first shaft 50, the belt 60, and the second shaft 70 to the rotation axis of the dynamo in the power generation section 80 by the second transmission section 30b. When the power is transmitted to the dynamo, the rotating shaft of the dynamo rotates due to the transmitted rotational force, so that the dynamo can generate electricity.

(configuration - other configurations)
In addition to this, the power generation system 1 can be configured with any possible structure. Specifically, in Embodiment 1, the first transmission portion 30a and the second transmission portion 30b are formed so that the rotation speeds of the first transmission portion 30a and the second transmission portion 30b are substantially the same. However, it is not limited to this. For example, when the movement efficiency of the pressing portion 20 differs depending on the direction of relative linear movement of the pressing portion 20, either the first transmission portion 30a or the second transmission portion 30b may The first transmission portion 30a or the second transmission portion 30b may be formed so as to rotate at a lower speed or a higher speed than the other of the second transmission portions 30b. As an example, when the movement efficiency when the pressing portion 20 relatively linearly moves in the rearward upper oblique direction is lower than the movement efficiency when the pressing portion 20 relatively linearly moves in the forward downward oblique direction. For this purpose, the diameter of the first transmission portion 30a is made smaller than the diameter of the second transmission portion 30b (or the number of protrusions 40 of the first transmission portion 30a is reduced to the number of protrusions 40 of the second transmission portion 30b ), the first transmission part 30a may be formed as a high-speed ratchet gear and the second transmission part 30b may be formed as a low-speed ratchet gear. With such a configuration, when the movement efficiency of the pressing portion 20 differs depending on the direction of relative linear movement of the pressing portion 20, pressing can be performed by changing the rotation speed of the first transmission portion 30a or the second transmission portion 30b. Since the movement efficiency of the unit 20 can be improved, the power generation efficiency of the power generation system 1 can be maintained.

In addition, in the first embodiment, the moving direction of the relative linear movement of the pressing portion 20 is the front-rear, up-down, up-down, and oblique directions. . In this case, when the pressing portion 20 is relatively linearly moved rearward by the horizontal component force of the wave and the horizontal component force is no longer applied to the receiving portion 22, for example, the pressing portion 20 is returned to its original position. The pressing portion 20 may be relatively linearly moved forward by a known restoring means (for example, a spring, an elastic member such as rubber, etc.) for returning to the position.

Further, in Embodiment 1, the pressing portion 20, the first transmission portion 30a, and the second transmission portion 30b are arranged such that the imaginary planes are orthogonal to the left-right direction (so-called vertically placed state). However, it is not limited to this, and for example, it may be arranged such that the virtual surface is substantially horizontal (so-called horizontal placement state).

Further, in Embodiment 1, one set consisting of the pressing portion 20, the first transmission portion 30a, the second transmission portion 30b, the first shaft 50, the belt 60, the second shaft 70, and the power generation portion 80 is provided. Although it has been explained that there is, it is not limited to this. 8 and 9 are diagrams showing modifications of the power generation system 1 according to Embodiment 1. FIG. For example, as shown in FIG. 8, a plurality of sets may be provided in order to improve the amount of power generation. In this case, as shown in FIG. 8, each set of pressing portions 20 may include a receiving portion 22 and a connecting portion 23, respectively. In addition, although the length of these connecting portions 23 in the front-rear direction is arbitrary, for example, they may be set to lengths corresponding to the height of the water surface (so-called tide level). Set the height to be shorter than the length corresponding to low tide. Alternatively, as shown in FIG. 9 , a common receiving portion 22 may be provided for a plurality of sets of pressing portions 20 . 8, the accommodating portion 10 may be provided for each group, or the accommodating portion 10 common to a plurality of groups may be provided, but in the modified example of FIG. , a common housing portion 10 is provided for a plurality of sets.

Further, in Embodiment 1, it has been described that one set of the first transmission portion 30a, the second transmission portion 30b, and the first shaft 50 is provided for one pressing portion 20. Not limited. FIG. 10 is a diagram showing a modification of the power generation system 1 according to the first embodiment. For example, as shown in FIG. 10, a plurality of sets may be provided for one pressing portion 20 in order to improve the amount of power generation. In this case, as shown in FIG. 10, a plurality of sets of the first transmission portion 30a, the second transmission portion 30b, and the first shaft 50 are arranged side by side along the front-rear direction. Also, a belt 60, a second shaft 70, and a power generation section 80 are provided for each set.

Further, in Embodiment 1, it has been described that one set of the first transmission portion 30a and the second transmission portion 30b is provided for one first shaft 50, but the present invention is not limited to this. FIG. 11 is a diagram showing a modification of the power generation system 1 according to Embodiment 1. FIG. For example, as shown in FIG. 11, a plurality of sets may be provided for one first shaft 50 (in the example of FIG. 11, three sets of the first transmission portion 30a and the second transmission portion 30b are provided). ). In this case, for example, the rotation speed of each pair of the first transmission portion 30a and the second transmission portion 30b is set to be different so that the pressing portion 20 can perform relative linear movement according to wave conditions. (For example, the rotation speed of the first set is set to the highest speed, the rotation speed of the second set is set to the lowest speed, and the rotation speed of the third set is the same as the rotation speed of the first set and the rotation speed of the second set. set to an intermediate speed between the rotation speed of the As a result, for example, when the wave height is relatively low, only the first pair (or the first pair and the second pair) of the first transmission portion 30a and the second transmission portion 30b can be rotated. When the wave height is relatively high due to the influence, the first transmission part 30a and the second transmission part 30b of each of the first, second, and third sets can be rotated. Relative linear movement of the pressing portion 20 can be performed at a constant speed, and the power generation efficiency of the power generation system 1 can be maintained. Alternatively, without being limited to this, for example, the rotational speed of each pair of the first transmission portion 30a and the second transmission portion 30b may be set to be the same.

Further, in Embodiment 1, the first transmission portion 30a and the second transmission portion 30b are provided as the transmission means, and the first tooth portion 24 and the second tooth portion 25 are provided as the tooth portions. However, it is not limited to this. 12 and 13 are diagrams showing modifications of the power generation system 1 according to the first embodiment. For example, as shown in FIG. 12, in addition to the first transmission section 30a and the second transmission section 30b, the third transmission section 30c (third transmission section) and the fourth transmission section 30d (fourth transmission section) are used as transmission means. ) may be provided, and a third tooth portion 27 may be provided as a tooth portion in addition to the first tooth portion 24 and the second tooth portion 25 .

The third transmission portion 30c is a transmission means for transmitting a rotational force in the rotation direction of power generation, which will be described later, to the dynamo of the power generation portion 80, which will be described later, by rotating itself. Like the first transmission portion 30a, the third transmission portion 30c is configured using a known ratchet gear or the like that is rotatable only in the same direction as the power generation rotation direction. 30a and the second transmission portion 30b (specifically, located on the left side of the first transmission portion 30a), and fixed to the first shaft 50 by a fixture or the like. Fixed.

The fourth transmission portion 30d is transmission means for rotating the third transmission portion 30c as the fourth transmission portion 30d rotates. The fourth transmission portion 30d is configured using, for example, a known spur gear or the like, and is arranged at a position where it can come into contact with the third transmission portion 30c (specifically, on the lower side than the third transmission portion 30c). ) and fixed to a shaft (not shown) rotatably fixed to the housing portion 10 by a fixture or the like.

The third tooth portion 27 is for pressing the fourth transmission portion 30d, has a plurality of protrusions 26, and is arranged so as to be in contact with the fourth transmission portion 30d. As for the details of the installation method of the third tooth portion 27, for example, as shown in FIG. a sixth frame portion (not shown) connecting the front portion of the first frame portion 21a and the front portion of the fifth frame portion 21e; and the rear portion of the first frame portion 21a. A seventh frame portion (not shown) connecting the side portion and the rear portion (not shown) of the fifth frame portion 21e is provided. Among these frame portions, the third tooth portion 27 is arranged along the moving direction of the relative linear movement of the pressing portion 20 at the end portion of the horizontal rod portion of the fifth frame portion 21e on the side of the fourth transmitting portion 30d. installed.

Here, regarding the shape of the protrusion 26 in each of the first tooth 24, the second tooth 25, and the third tooth 27, specifically, when the receiving portion 22 receives a wave force or the like, the pressing portion 20 rotationally moves toward one of the rotational directions (clockwise rotational direction) in the in-plane rotation of the virtual plane, the first transmission portion 30a and the second transmission portion 30a are rotated by the first tooth portion 24 and the second tooth portion 25. When the portion 30b is pressed and rotates in the power generation rotation direction, and the pressing portion 20 rotates in the other rotation direction (counterclockwise rotation direction) in the in-plane rotation of the imaginary plane, the third tooth portion The third transmission portion 30c is pressed by the third transmission portion 30d via the fourth transmission portion 30d by the third transmission portion 27 to rotate in the power generation rotation direction. More specifically, the projections 26 of the first toothed portion 24 and the second toothed portion 25 are formed in the same shape as in the first embodiment. Regarding the shape of the protrusion 26 of the third tooth 27, the protrusion 26 of the third tooth 27 and the protrusion of the fourth transmission part 30d are different regardless of the rotation direction of the in-plane rotation of the imaginary plane of the pressing part 20. 40, the third transmission portion 30c is pressed by the third tooth portion 27 via the fourth transmission portion 30d (even if the third transmission portion 30c is pressed, the third The third transmission portion 30c does not rotate unless the internal ratchet of the transmission portion 30c meshes with the fourth transmission portion 30d), and is formed in a substantially equilateral triangle shape protruding upward.

With such a structure, when the pressing portion 20 rotates regardless of the rotational direction of the in-plane rotation of the virtual plane, the pressing portion 20 causes the first transmission portion 30a, the second transmission portion 30b, or the third transmission portion to move. 30c can be pressed so as to rotate in the direction of power generation rotation. Therefore, compared to the case where the third transmission portion 30c, the fourth transmission portion 30d, and the third tooth portion 27 are not provided, power generation can be performed regardless of the rotation direction of the in-plane rotation of the imaginary plane of the pressing portion 20. Therefore, the amount of power generation can be increased. Further, according to the shape of the projecting portion 26 of the third tooth portion 27, when the pressing portion 20 moves relatively linearly upward and backward, the third transmitting portion 30c moves toward the third tooth portion 27. is pushed through the fourth transmission portion 30d by the fourth transmission portion 30d, the internal ratchet of the third transmission portion 30c and the fourth transmission portion 30d do not mesh with each other, so that the fourth transmission portion 30d can idle. On the other hand, when the pressing portion 20 moves relatively linearly forward and downward, the third transmission portion 30c is pressed by the third tooth portion 27 via the fourth transmission portion 30d, and the third The inner ratchet of the transmission portion 30c and the fourth transmission portion 30d are meshed to rotate in the power generation rotation direction.

In addition, in the modified example of FIG. 12, it is explained that one fourth transmission portion 30d that can come into contact with the third transmission portion 30c is provided, but the present invention is not limited to this. For example, a plurality of fourth transmission portions 30d may be provided along the periphery of the third transmission portion 30c. As a result, when the in-plane rotation angle of the imaginary plane of the pressing portion 20 is relatively small, the third transmitting portion 30c and a part of the plurality of fourth transmitting portions 30d are brought into contact with each other, and the imaginary plane of the pressing portion 20 is rotated. When the angle of in-plane rotation is relatively large, the third transmission portion 30c and another portion of the plurality of fourth transmission portions 30d can be brought into contact. Therefore, regardless of the magnitude of the in-plane rotation angle of the imaginary plane of the pressing portion 20, the third tooth portion 27 can press the third transmitting portion 30c via the fourth transmitting portion 30d. Further, in the modified example of FIG. 12, it is explained that one set of the third transmission portion 30c, the fourth transmission portion 30d, and the third tooth portion 27 is provided, but the present invention is not limited to this. For example, a plurality of the sets may be provided, and as an example, as shown in FIG. 13, in the power generation system 1 of FIG. may In this case, in order to stably perform the relative linear movement of the pressing portion 20, the additional set of fourth transmission portions 30d is arranged below the additional set of third tooth portions 27. In addition, the additional set of third transmission portions 30c may be arranged below the additional set of fourth transmission portions 30d. Further, the shape of the protrusion 26 of the third tooth portion 27 of the added set may be formed in a substantially equilateral triangular shape that protrudes downward.

Further, in Embodiment 1, the internal shape of the first housing portion 11 and the second housing portion 12 of the housing portion 10 is formed in an oval ring shape, but it is not limited to this, and can be formed in various shapes. may be formed by 14A and 14B are diagrams showing a modification of the accommodating portion 10 according to Embodiment 1. FIG. For example, as shown in FIG. 14, the internal shape of the first housing portion 11 is a rectangular ring with an open upper surface (specifically, a rectangular ring longer than the vertical length of the inner diameter of the first housing portion 11). Or, the internal shape of the second housing portion 12 is a rectangular ring with an open top (specifically, a rectangular ring that is approximately the same as the inner diameter of the land-side end of the first housing portion 11). may be formed by

(effect)
As described above, according to Embodiment 1, the pressure portion 20, the first transmission portion 30a, or the pressing portion 20, the first transmission portion 30a, or When a wave force (external force) is applied to the second transmission portion 30b, the first transmission portion 30a, the second transmission portion 30b, and the pressing portion 20 move relatively linearly along an imaginary plane. Thus, the pressing portion 20 is formed so that either one of the first transmission portion 30a or the second transmission portion 30b is pressed by the pressing portion 20 to rotate, and the dynamo of the power generation portion 80 is formed relative to the When the target linear movement is movement in one movement direction of the relative linear movement, the rotation shaft is rotated by the rotational force transmitted by the first transmission portion 30a to generate power. When the linear movement is movement in the other moving direction of the relative linear movement, the rotational force transmitted by the second transmission portion 30b rotates the rotating shaft to generate power. Since the transmission part 30a and the second transmission part 30b can be configured with commercially available parts (specifically, known ratchet gears, etc.), there is no need to configure them with a special structure, so power generation It is possible to improve the manufacturability of the system 1 and reduce the manufacturing cost.

Further, when the relative linear movement is movement in one movement direction of the relative linear movement, the first transmission part 30a is pressed by the first tooth part 24 to rotate in the power generation rotation direction, When the relative linear movement is movement in the other movement direction of the relative linear movement, the second transmission part 30b is pressed by the second tooth part 25 to rotate in the power generation rotation direction. Since the first toothed portion 24 and the second toothed portion 25 are formed, it is not necessary to provide an adjustment means for adjusting the rotation direction of the first transmission portion 30a or the second transmission portion 30b to coincide with the power generation rotation direction. Therefore, the manufacturing cost of the power generation system 1 can be reduced.

The pressing portion 20 includes a body portion 21 having a first tooth portion 24 and a second tooth portion 25, and a receiving portion 22 located below the body portion 21, which receives the horizontal component force of the wave force. A receiving portion 22 and a connecting portion 23 connecting the main body portion 21 and the receiving portion 22 are provided. In this case, either the first tooth portion 24 or the second tooth portion 25 is moved linearly in the upward oblique direction, which is one of the moving directions of the relative linear movement, of the pressing portion 20 . Either one of the first transmission portion 30a and the second transmission portion 30b is pressed by one side to rotate and move, and after the pressing portion 20 linearly moves in the oblique upward direction, a horizontal component force is applied to the receiving portion 22. When the first tooth is lost, the pressing portion 20 moves linearly in the diagonally downward direction, which is the other of the moving directions of the relative linear movement, as the weight of the pressing portion 20 drops. The first transmission portion 30a and the second transmission portion 30a are rotated by the other of the portion 24 and the second tooth portion 25 so that the other of the first transmission portion 30a and the second transmission portion 30b is pressed to rotate. 30b and the pressing portion 20 are installed, when the pressing portion 20 moves relatively linearly in the vertical and oblique directions, power can be generated using the wave force and the weight of the pressing portion 20. Compared to the case of generating power using only the power generation system 1, it is possible to reliably generate power in the power generation system 1 regardless of the moving direction of the relative linear movement.

Further, when the pressing portion 20 relatively linearly moves in the upward oblique direction, the wave water flows into the receiving portion 22, and when the pressing portion 20 relatively linearly moves in the downward oblique direction. Since the receiving portion 22 is formed so that the water that has been applied flows out to the outside of the receiving portion 22, the weight of the water that has flowed into the receiving portion 22 causes the pressing portion 20 to relatively move downward in a straight line. As compared with the case where the receiving portion 22 is formed so that wave water does not flow into the receiving portion 22, the pressing portion 20 can be relatively linearly moved more reliably.

Further, the internal shape of the housing portion 10 is such that the internal water level of the housing portion 10 is amplified by the waves flowing into the housing portion 10, thereby promoting the relative linear movement of the pressing portion 20. , the internal water level of the housing portion 10 can be amplified when waves flow into the housing portion 10, and the inflow The water level inside the accommodation portion 10 can be quickly lowered when the wave that has been applied flows out to the outside of the accommodation portion 10 . Therefore, the relative linear movement of the pressing portion 20 can be effectively performed, and the power generation amount of the power generation system 1 can be increased.

[Embodiment 2]
Next, Embodiment 2 will be described. This form is different from the first embodiment, and is a form of generating power using the horizontal component of wave force. Components that are substantially the same as those of the first embodiment are given the same reference numerals or names as used in the first embodiment, and the description thereof is omitted.

(composition)
First, the configuration of the power generation system according to Embodiment 2 will be described. FIG. 15 is an enlarged right side view showing the power generation system according to Embodiment 2, and shows a region corresponding to FIG. FIG. 16 is a right side view showing a state in which the pressing portion has linearly moved relative to the transmitting portion toward the rear and upward oblique directions. FIG. 17 is a right side view showing a state in which the pressing portion has moved relatively linearly forward and downward with respect to the transmitting portion. As shown in FIG. 15, the power generation system 100 according to Embodiment 2 includes a housing portion (not shown), a pressing portion 20, a transmission portion 90, a first shaft (not shown), a belt (not shown), a second shaft (illustration omitted), and a power generation unit (illustration omitted).

(Construction - transmission part, first shaft)
The transmission part 90 is configured using, for example, a known gear or the like having a plurality of protrusions 91, and is fixed to the first shaft by a fixture or the like. Further, the first shaft is for transmitting the rotational force transmitted from the transmission part 90 to the belt, and as shown in FIG. there is

(Construction - pressing part)
The pressing portion 20 includes a body portion (not shown), a receiving portion (not shown), and a connection portion (not shown). Among them, the main body portion is formed in a rectangular annular shape with a relatively thick side wall (that is, a receiving hole 28 is formed inside the main body portion). Here, regarding the shape of the accommodation hole 28, in the second embodiment, the transmission part 90 can be accommodated in the accommodation hole 28, and the horizontal component force of the wave force exerts on the pressing part 20 within the imaginary plane. is formed in a shape capable of ensuring a predetermined amount of movement (so-called stroke) when the pressing portion 20 moves relatively linearly when the pressure is applied. Specifically, as shown in FIG. 15, the length of the receiving hole 28 in the longitudinal direction (substantially in the front-rear direction) is longer than the length in the front-rear direction of the transmission portion 90 (for example, the length of the transmission portion 90 in the front-rear direction). ), and the length of the accommodation hole 28 in the lateral direction (substantially in the vertical direction) is substantially the same as the length in the vertical direction of the transmission portion 90 .

Further, a first toothed portion 24 is provided on the upper end side of the accommodation hole 28 in the main body, and a second toothed portion 25 is provided on the lower end side of the accommodation hole 28 in the main body. Specifically, the first toothed portion 24 and the second toothed portion 25 are arranged so as to be able to contact the transmission portion 90 and along the moving direction of the relative linear movement. Here, the shape of the protruding portion 26 in each of the first tooth portion 24 and the second tooth portion 25 is arbitrary, but in Embodiment 2, as shown in FIG. (Specifically, when the transmission portion 90 is relatively linearly moved toward the rear and upward oblique direction), the transmission portion 90 is pressed by the first tooth portion 24 to rotate in the power generation rotation direction, and as shown in FIG. When the pressing portion 20 moves relatively linearly in an oblique downward direction (specifically, in an oblique forward and downward direction), the transmission portion 90 is pressed by the second tooth portion 25 so as to rotate in the power generation rotation direction. is formed in Specifically, the shape of the protruding portion 26 of the first tooth portion 24 is substantially the same as the shape of the first tooth portion 24 according to Embodiment 1, and the protruding portion 26 of the first tooth portion 24 It is formed in a shape that protrudes at an angle toward the Further, the shape of the protruding portion 26 of the second tooth portion 25 is substantially the same as the shape of the second tooth portion 25 according to Embodiment 1, and the protruding portion 26 of the second tooth portion 25 is inclined forward and upward. It is formed in a shape that protrudes in a downward direction. With such a shape, when the pressing portion 20 moves relatively linearly, the transmitting portion 90 can be pressed by the pressing portion 20 so as to rotate in the power generation rotation direction regardless of the moving direction of the relative linear movement. Since it is not necessary to provide an adjustment unit for adjusting the rotation direction of the transmission unit 90 to match the power generation rotation direction, the manufacturing cost of the power generation system 100 can be reduced.

(Construction - details of the installation position of the pressing part and the transmission part)
Next, the installation positions of the pressing portion 20 and the transmission portion 90 will be described. Regarding the details of the installation positions of the pressing portion 20 and the transmitting portion 90, in the second embodiment, as shown in FIG. When the pressing portion 20 is pushed upward, the transmitting portion 90 is pressed by the main body portion (not shown) and rotates due to the relative linear movement of the pressing portion 20 in the upward oblique direction (specifically, in the rearward upward oblique direction). As shown in FIG. 17 , when the pressing portion 20 moves relatively linearly in the oblique upward direction and the horizontal component force is no longer applied to the receiving portion, the weight of the pressing portion 20 falls. Along with this, the pressing portion 20 is relatively linearly moved in an obliquely downward direction (specifically, in an obliquely forward and downward direction), so that the transmission portion 90 is pressed by the main body portion and is rotated. 20 and a transmission part 90 are arranged. Specifically, as shown in FIG. 15, in a state in which the transmission portion 90 is accommodated along the virtual plane inside the accommodation hole 28 of the main body portion, the projection portion 91 of the transmission portion 90 and the first tooth portion 24 are aligned. and the projections 26 of the second teeth 25 are installed so as to be able to come into contact with each other.

With the structure of the power generation system 100 as described above, even when the power generation system 100 is installed on land (breakwater) in substantially the same manner as the power generation system 1 according to Embodiment 1, it is possible to obtain a horizontal component force necessary for power generation. can be used, and a desired power generation amount can be generated using the horizontal component force.

(Configuration - function of power generation system)
Functions of the power generation system 100 configured in this way will be described.

First, for example, as shown in FIG. 16, when the horizontal component force of the wave is applied to the receiving portion 22 within the plane of the virtual plane, the pressing portion 20 moves relatively linearly upward and backward. do. In this case, the transmission portion 90 is pressed by the first tooth portion 24 of the pressing portion 20 and rotates in the power generation rotation direction (clockwise rotation direction). The horizontal component of force is converted into a rotational force in the power generation rotation direction (clockwise rotation direction). Then, when the converted rotational force in the power generation rotation direction (clockwise rotation direction) is transmitted to the rotation shaft of the dynamo in the power generation section by the transmission section 90 via the first shaft, the belt, and the second shaft, The dynamo can generate power by rotating the rotating shaft of the dynamo by the transmitted rotational force.

Further, for example, as shown in FIG. 17, when the horizontal component force is no longer applied to the receiving portion after the pressing portion 20 has moved relatively linearly upward and backward, the self weight of the pressing portion 20 Along with the descent, the pressing portion 20 relatively linearly moves forward and downward. In this case, the transmission portion 90 is pressed by the second tooth portion 25 of the pressing portion 20 to rotate in the power generation rotation direction (clockwise rotation direction). The self-gravity of the pressing portion 20 is converted into a rotational force in the power generation rotation direction (clockwise rotation direction). Then, when the converted rotational force in the power generation rotation direction (clockwise rotation direction) is transmitted to the rotation shaft of the dynamo in the power generation section by the transmission section 90 via the first shaft, the belt, and the second shaft, The dynamo can generate power by rotating the rotating shaft of the dynamo by the transmitted rotational force.

(effect)
As described above, according to the second embodiment, when the pressing portion 20 moves relatively linearly in the oblique upward direction, the transmission portion 90 is pressed by the first tooth portion 24 and rotates in the power generation rotation direction, When the pressing portion 20 moves relatively linearly in an oblique downward direction, the transmission portion 90 is pressed by the second tooth portion 25 and rotates in the power generation rotation direction. Since the two-toothed portion 25 is formed, when the pressing portion 20 moves relatively linearly, regardless of the moving direction of the relative linear movement, the pressing portion 20 rotates the transmission portion 90 in the power generation rotation direction. It is possible to reliably generate power in the power generation system 100 regardless of the moving direction of the relative linear movement.

[Embodiment 3]
Next, Embodiment 3 will be described. This form is a form which generates electric power using the vertical component force of wave force. Components that are substantially the same as those of the first embodiment are given the same reference numerals or names as used in the first embodiment, and the description thereof is omitted.

(composition)
First, the configuration of the power generation system according to Embodiment 3 will be described. FIG. 18 is a schematic diagram showing a power generation system according to Embodiment 3. FIG. As shown in FIG. 18, a power generation system 200 according to Embodiment 3 includes a pressing portion 20, a first transmission portion (not shown), a second transmission portion 30b, a first shaft 50, a belt (not shown), a second It has a shaft (not shown) and a power generator (not shown).

(Construction - pressing part)
As shown in FIG. 18, the pressing portion 20 includes a main body portion 21, a support frame portion 110, a connecting bar 111, a first floating body portion 112, a second floating body portion 113, a tooth portion 114, and a third floating body portion 115. there is

(Configuration - pressing part - body part)
As shown in FIG. 18, the body portion 21 is arranged such that the longitudinal direction of the first frame portion 21a (or the second frame portion 21b) is substantially along the vertical direction.

(Construction - pressing part - support frame part)
The support frame portion 110 is support means for supporting the body portion 21 . Further, the support frame portion 110 is configured by combining a plurality of frame portions. Specifically, as shown in FIG. 18, the plurality of frame portions are a rectangular ring-shaped first frame portion 110a and a rectangular ring-shaped second frame, which are provided on the left side of the first frame portion 110a. A second frame (not shown) and a linear third frame portion connecting the rear end portion of the upper portion of the first frame portion 110a and the rear end portion of the upper portion of the second frame portion. A frame portion (not shown) and a linear fourth frame portion connecting the rear end portion of the lower portion of the first frame portion 110a and the rear end portion of the lower portion of the second frame portion. 4 frame parts (not shown). Further, the support frame portion 110 is arranged so as to cover a part of the body portion 21 from the outside, and has a connection structure (for example, a fitting structure, etc.) capable of allowing the movement of the body portion 21 in the vertical direction. ) is connected to the main body 21 . In addition, although the method of installing the first transmission portion, the second transmission portion 30b, and the first shaft 50 with respect to the support frame portion 110 is arbitrary, in Embodiment 3, as shown in FIG. After the transmission portion and the second transmission portion 30b are arranged side by side in the left-right direction with a space therebetween, the first transmission portion and the second transmission portion 30b are fixed to the first shaft 50 by a fastener or the like. do. At least one of the left and right end portions of the first shaft 50 is fixed to the support frame portion 110 by a rotatable fixture or the like (for example, a ball bearing or the like).

(Configuration - pressing part - connection bar)
The connecting bar 111 is connecting means for connecting the support frame portion 110 , the first floating body portion 112 , the second floating body portion 113 , the tooth portion 114 and the third floating body portion 115 . The connecting bar 111 is formed of a rod-like body, and is located between the support frame portion 110 and the first floating body portion 112, between the first floating body portion 112 and the second floating body portion 113, and between the second floating body portion 113 and the second floating body portion. The supporting frame portion 110, the first floating body portion 112, the second floating body portion 113, the tooth portion 114 are arranged between the portion 113 and the tooth portion 114 and between the tooth portion 114 and the third floating body portion 115, respectively. , and the third floating body portion 115 by a fixture or the like (Note that in the connecting bar 111 between the second floating body portion 113 and the tooth portion 114, the connecting bar 111 rotates in the front-rear direction. is connected to the second floating body portion 113 by a fixture or the like that is capable of such rotation).

(Construction-pressing part-first floating body part, second floating body part)
The first floating body part 112 and the second floating body part 113 are such that at least a part of the first floating body part 112 and the second floating body part 113 can float on the surface of the water. It supports part of the portion 30b, the first shaft 50, the belt, the second shaft, the power generation portion, the body portion 21, and the connecting bar 111. The first floating body portion 112 and the second floating body portion 113 are substantially spherical bodies (or polygonal bodies (eg rectangular parallelepipeds, etc.)) made of, for example, metal material, resin material, or wood, and float on the surface of the water. , and is connected to the connecting bar 111 by a fixture or the like.

(Construction - pressing part - tooth part)
The tooth portion 114 is for pressing the body portion 21 . As shown in FIG. 18, the tooth portion 114 is formed of a relatively thick fan-shaped plate-like body, is arranged at a position where it can contact the support frame portion 110, and is attached to the connecting bar 111. are connected by means of fixtures or the like. Further, although the method of pressing the tooth portion 114 and the main body portion 21 is arbitrary, in the third embodiment, as shown in FIG. 114a, and a third tooth portion 116 having a plurality of projections 116a is provided at a contact portion of the first frame portion 21a of the main body portion 21 with the support frame portion 110, whereby the projection portion 114a of the tooth portion 114 and the third The tooth portion 114 and the main body portion 21 are pressed by meshing with the projection portion 116 a of the three-tooth portion 116 .

(Construction-pressing portion-third floating body portion)
At least a portion of the third floating body portion 115 can float on the water surface, and receives the vertical component force of the wave force. As shown in FIG. 18, the third floating body section 115 is a substantially box-shaped body (for example, a rectangular parallelepiped) made of, for example, a metal material, a resin material, or a wooden material. Compared to 112 and the second floating body portion 113, it floats in a vertically swingable state, and is connected to the connecting bar 111 by a fixture or the like.

With the structure of the power generation system 200 as described above, even when the power generation system 200 is installed offshore, it is possible to obtain the vertical force component required for power generation. It can generate electricity.

(Configuration - function of power generation system)
Functions of the power generation system 200 configured in this way will be described.

First, for example, when a vertical component force of a wave force is applied to the third floating body portion 115, the main body portion 21 is pressed by the tooth portion 114, thereby causing the main body portion 21 to move downward. move in a straight line. In this case, the second transmission portion 30b is pressed by the second tooth portion 25 of the pressing portion 20 and rotationally moves in the power generation rotation direction (clockwise rotation direction). The portion 25 converts the self-gravity of the pressing portion 20 into a rotational force in the power generation rotation direction (clockwise rotation direction). Then, the converted rotational force in the power generation rotation direction (clockwise rotation direction) is transmitted to the rotating shaft of the dynamo in the power generation section by the second transmission section 30b via the first shaft 50, the belt, and the second shaft. Then, the rotating shaft of the dynamo rotates due to the transmitted rotational force, so that the dynamo can generate electricity.

Further, when the vertical component force is no longer applied to the third floating body portion 115 after the main body portion 21 relatively moves downward in a straight line, the main body portion 21 is pressed by the tooth portion 114, , the body portion 21 moves relatively linearly upward. In this case, the first transmission portion and the first tooth portion 24 are pressed by the first tooth portion 24 of the pressing portion 20 to rotate in the power generation rotation direction (clockwise rotation direction). , the vertical component force is converted into a rotational force in the direction of power generation rotation (clockwise rotation direction). Then, the converted rotational force in the power generation rotation direction (clockwise rotation direction) is transmitted to the rotating shaft of the dynamo in the power generation section by the first transmission section via the first shaft 50, the belt, and the second shaft. Then, the rotating shaft of the dynamo is rotated by the transmitted rotational force, so that the dynamo can generate electricity.

(configuration - other configurations)
In addition to this, the power generation system 200 can be configured with any possible structure. Specifically, in Embodiment 3, the pressing portion 20 includes a body portion 21, a support frame portion 110, a connecting bar 111, a first floating body portion 112, a second floating body portion 113, a tooth portion 114, and a third floating body portion. 115, but this is not the only option. FIG. 19 is a diagram showing a modification of power generation system 200 according to Embodiment 3. In FIG. For example, as shown in FIG. 19, the pressing portion 20 may include a vibration suppressing portion 117 in addition to the components described above. The sway suppressing portion 117 is a sway suppressing means for suppressing the swaying of the first floating body portion 112 or the second floating body portion 113 . The swaying suppression part 117 is formed of a long rod-like body, and is arranged so that the longitudinal direction of the swaying suppression part 117 is in the vertical direction below the first floating body part 112 and the second floating body part 113. It is connected to each of the first floating body part 112 and the second floating body part 113 by means of fixtures or the like, and is also connected to an anchor part 118 placed on the seabed via a rope 119 . With such a configuration, the shaking of the first floating body portion 112 and the second floating body portion 113 can be suppressed, so that the installation stability of the power generation system 200 can be improved.

(effect)
As described above, according to Embodiment 3, in the case where the movement direction of the relative linear movement is the vertical direction, when the vertical component force of the wave force is applied to the third floating body portion 115, the tooth portion 114 When the body portion 21 is pressed by the first tooth portion 24 or the second tooth portion Either one of the first transmission portion and the second transmission portion 30b is pressed by either one of the transmission portions 25 to rotate, and after the main body portion 21 relatively linearly moves downward, the vertical component force reaches the third position. When it is no longer applied to the floating body portion 115, the main body portion 21 is pressed by the tooth portion 114, so that the pressing portion 20 moves upward, which is the other of the moving directions of the relative linear movement. The linear movement causes the other of the first transmission portion 24 and the second tooth portion 25 to press the other of the first transmission portion and the second transmission portion 30b to rotate. section, the second transmission section 30b, and the pressing section 20 are installed, the vertical component force required for power generation can be obtained even when the power generation system 200 is installed offshore. can be used to generate a desired amount of power generation.

[Embodiment 4]
Next, Embodiment 4 will be described. This form is different from the third embodiment, and is a form in which power is generated using the vertical force component of wave force. Components that are substantially the same as those of the first embodiment are given the same reference numerals or names as used in the first embodiment, and the description thereof is omitted.

(composition)
First, the configuration of the power generation system according to Embodiment 4 will be described. FIG. 20 is a schematic diagram showing a power generation system according to Embodiment 4. FIG. As shown in FIG. 20, a power generation system 300 according to Embodiment 4 includes a first floating body portion 120, a pressing portion 20, a first transmission portion (not shown), a second transmission portion 30b, a first shaft 50, a belt ( (illustration omitted), a second shaft (illustration omitted), and a power generation section (illustration omitted).

(Configuration - first floating body section)
The first floating body part 120 is such that at least part of the first floating body part 120 can float on the water surface, and as shown in FIG.

(Configuration - first floating body part - main body of first floating body part)
The first floating body section main body 121 is the basic structure of the first floating body section 120 . Here, the "first floating body section main body 121" includes, for example, a combination of only members having a floating function, a combination of a member having a floating function and a member not having a floating function, and the like. It is a concept (the same applies to the second floating body portion 124 described later). The first floating body section main body 121 is a long, hollow, substantially cylindrical body made of, for example, a metal material, a resin material, or the like, and floats on the surface of the water. In addition, although the installation method of the first floating body section main body 121 is arbitrary, in the fourth embodiment, from the viewpoint of ensuring the stability of installation of the first floating body section 120, most of the first floating body section main body 121 is It is installed so that it can be kept in the water. Specifically, as shown in FIG. 20, approximately half of the main body 121 of the first floating body (or a slightly larger amount) is filled with water (the rest is filled with air). , water is allowed to flow into the first floating body portion main body 121 through an opening formed at the lower end portion of the first floating body portion main body 121 . Further, as shown in FIG. 20 , a return portion 123 is provided at the lower end portion of the first floating body portion main body 121 . The return portion 123 is suppressing means for suppressing vertical or horizontal vibration of the first floating body portion main body 121. It is formed so as to protrude toward the outside of the direction.

(Configuration - first floating body section - support section)
The support part 122 is support means for supporting the first transmission part, the second transmission part 30b, and the first shaft 50 . As shown in FIG. 20, the support portion 122 is, for example, a long rod-shaped body made of the same material as the first floating body portion main body 121, and the longitudinal direction of the support portion 122 is substantially along the vertical direction. , and is connected to the first floating body section main body 121 by fixtures, welding, or the like so that the lower end of the support section 122 abuts on the upper end of the first floating section main body 121 . Moreover, the method of installing the first transmission portion, the second transmission portion 30b, and the first shaft 50 with respect to the support portion 122 is arbitrary, but in Embodiment 4, as shown in FIG. and the second transmission portion 30b are spaced apart from each other and arranged side by side along the left-right direction, and then the first transmission portion and the second transmission portion 30b are fixed to the first shaft 50 by a fastener or the like. It is installed by A fixture or the like (for example, a ball bearing or the like) capable of rotating a portion of the first shaft 50 between the first transmission portion and the second transmission portion 30b with respect to the center portion of the support portion 122 in the vertical direction is provided. ).

(Construction - pressing part)
The pressing portion 20 includes a main body portion 21, a pair of second floating body portions 124, and a pair of connecting portions 125, as shown in FIG.

(Configuration - pressing part - body part)
As shown in FIG. 20, the body portion 21 is arranged such that the longitudinal direction of the first frame portion 21a (or the second frame portion 21b) is substantially along the vertical direction. Moreover, although the method of installing the support portion 122 with respect to the main body portion 21 is arbitrary, in the fourth embodiment, as shown in FIG. ) is formed, and the support portion 122 is inserted into the formed through hole.

(Construction-pressing portion-second floating body portion)
At least a part of the pair of second floating body portions 124 can float on the water surface, and receives the vertical component force of the wave force while supporting the main body portion 21. be. The pair of second floating body portions 124 are generally box-shaped bodies (for example, rectangular parallelepipeds) made of, for example, metal material, resin material, wood, etc., and are located below the main body part 21 and above the water surface. , they float apart from each other in a state in which they can swing in the vertical direction at least as compared with the first floating body portion 120 .

(Construction-pressing part-connecting part)
The pair of connecting portions 125 connects the body portion 21 and the second floating body portion 124, and as shown in FIG. One of the pair of second floating body portions 124 is connected by a fixture, welding, or the like, and the other of the pair of connection portions 125 is the second frame portion 21b of the main body portion 21 and the other of the pair of second floating body portions 124. are connected by fixtures or welding, etc.

Due to the structure of the power generation system 300 as described above, even when the power generation system 300 is installed offshore, it is possible to obtain the vertical component force necessary for power generation. A desired power generation amount can be generated using the vertical force component.

(Configuration - function of power generation system)
Functions of the power generation system 300 configured in this way will be described.

First, for example, when a vertical component force of a wave force is applied to the pair of second floating body portions 124, the pressing portion 20 relatively linearly moves upward. In this case, the first transmission portion and the first tooth portion 24 are pressed by the first tooth portion 24 of the pressing portion 20 to rotate in the power generation rotation direction (clockwise rotation direction). , the vertical component force is converted into a rotational force in the direction of power generation rotation (clockwise rotation direction). Then, the converted rotational force in the power generation rotation direction (clockwise rotation direction) is transmitted to the rotating shaft of the dynamo in the power generation section by the first transmission section via the first shaft 50, the belt, and the second shaft. Then, the rotating shaft of the dynamo is rotated by the transmitted rotational force, so that the dynamo can generate electricity.

Further, for example, when the vertical component force is no longer applied to the pair of second floating body portions 124 after the pressing portion 20 relatively moves upward, The pressing portion 20 relatively linearly moves downward. In this case, the second transmission portion 30b is pressed by the second tooth portion 25 of the pressing portion 20 and rotationally moves in the power generation rotation direction (clockwise rotation direction). The portion 25 converts the self-gravity of the pressing portion 20 into a rotational force in the power generation rotation direction (clockwise rotation direction). Then, the converted rotational force in the power generation rotation direction (clockwise rotation direction) is transmitted to the rotating shaft of the dynamo in the power generation section by the second transmission section 30b via the first shaft 50, the belt, and the second shaft. Then, the rotating shaft of the dynamo rotates due to the transmitted rotational force, so that the dynamo can generate electricity.

(configuration - other configurations)
In addition to this, the power generation system 300 can be configured with any possible structure. Specifically, in Embodiment 4, the first floating body section 120 has been described as including the first floating body section main body 121 and the support section 122, but the present invention is not limited to this. 21 to 24 are diagrams showing modifications of the power generation system 300 according to the fourth embodiment. For example, in addition to the first floating body section main body 121 and the support section 122, a plurality of wings 126 may be provided as shown in FIGS. A wing portion 126 and a weight portion 127 may be provided. The plurality of wing portions 126 are suppressing means for suppressing vertical or horizontal vibration of the first floating body portion main body 121 . These plurality of wings 126 are elongated rectangular plate-like bodies made of, for example, a metal material or a resin material. As shown in FIG. It is arranged along the first floating body portion main body 121 and connected to the first floating body portion main body 121 by a fixture, welding, or the like. Further, the specific configuration of the wing portions 126 is not limited to providing a plurality of rectangular wing portions 126 shown in FIG. A single circular wing portion 126 shown in FIG. 24 may be provided, or a plurality of square wing portions 126 shown in FIG. 24 may be provided. With such a configuration, the installation stability of the first floating body part 120 can be improved.

(effect)
As described above, according to Embodiment 4, in the case where the movement direction of the relative linear movement is the vertical direction, when a vertical component force is applied to the pair of second floating body portions 124, the pressing portion 20 By linearly moving upward, which is one of the moving directions of the relative linear movement, either the first toothed portion 24 or the second toothed portion 25 causes the first transmission portion or the second transmission portion to move. 30b is pressed and rotated, and when the vertical component force is no longer applied to the pair of second floating body portions 124 after the pressing portion 20 linearly moves upward, the pressing portion As the weight of the pressing portion 20 drops, the pressing portion 20 linearly moves downward, which is the other of the moving directions of the relative linear movement. Since the first transmission portion, the second transmission portion 30b, and the pressing portion 20 are installed so that the other of the first transmission portion and the second transmission portion 30b is pressed by the other and is rotated, Even when the power generation system 300 is installed offshore, it is possible to obtain the vertical force component required for power generation. It is possible to generate a large amount of electricity.

[Embodiment 5]
Next, Embodiment 5 will be described. This form is different from the third and fourth embodiments, and is a form of generating power using the vertical force component of wave force. Components that are substantially the same as those of the first embodiment are given the same reference numerals or names as used in the first embodiment, and the description thereof is omitted.

(composition)
First, the configuration of the power generation system according to Embodiment 5 will be described. FIG. 25 is a schematic diagram showing a power generation system according to Embodiment 5. FIG. As shown in FIG. 25, a power generation system 400 according to Embodiment 5 includes a floating body portion 130, a pressing portion 20, a first transmission portion (not shown), a second transmission portion 30b, a first shaft 50, a belt (not shown), ), a second shaft (not shown), a power generator (not shown), and a spring portion 131 .

(Construction - Floating body)
The floating body part 130 is such that at least a part of the floating body part 130 can float on the surface of the water, and includes the pressing part 20, the first transmission part, the second transmission part 30b, the first shaft 50, the belt, the second shaft. , and the power generation unit, and receive the vertical component of the wave force. The floating body part 130 is, for example, a substantially hollow spherical body (or substantially hollow polygonal body (for example, substantially hollow rectangular parallelepiped)) formed of a metal material, a resin material, a wood material, or the like. Floating in a swingable state toward In addition, the floating body part 130 is connected to an anchor part 132 placed on the seabed via a rope 133 so as not to inadvertently move far away. Moreover, although the shape of the floating body portion 130 is arbitrary, in the fifth embodiment, the length of the floating body portion 130 in the front-rear direction (or the length in the left-right direction) is formed to be half or less of the wave wavelength. are doing. With such a shape, compared to the case where the length in the front-rear direction (or the length in the left-right direction) of the floating body portion 130 is the same as the wavelength of the waves, it becomes easier to swing in the vertical direction, so the amount of power generation is reduced. can be improved.

(Construction - pressing part)
The pressing portion 20 includes a body portion 21 (excluding the third frame portion 21c). As shown in FIG. 25, the body portion 21 is arranged such that the longitudinal direction of the first frame portion 21a (or the second frame portion 21b) is substantially along the vertical direction. Moreover, although the method of installing the main body portion 21 on the floating body portion 130 is arbitrary, in Embodiment 5, as shown in FIG. It is installed by being connected to the lower end of the floating body part 130 by means of fixtures, welding, or the like.

(Construction - spring part)
The spring portion 131 is a moving means for vertically moving the first transmission portion and the second transmission portion 30b. The spring portion 131 is configured using, for example, a known spring member such as a spring (specifically, a spring member having a damping constant of less than 1). In the upper part, the expansion and contraction direction of the spring part 131 is arranged along the vertical direction, and the upper end part of the spring part 131 is connected to the upper end part of the floating body part 130 by a fixture, welding, or the like. Moreover, although the method of installing the first transmission portion, the second transmission portion 30b, and the first shaft 50 with respect to the spring portion 131 is arbitrary, in Embodiment 5, as shown in FIG. After the transmission portion and the second transmission portion 30b are arranged side by side in the left-right direction with a space therebetween, the first transmission portion and the second transmission portion 30b are fixed to the first shaft 50 by a fastener or the like. do. Then, the first shaft 50 is installed by fixing it to the connection portion 134 attached to the spring portion 131 by a rotatable fixture or the like (for example, a ball bearing or the like). Due to such installation, when the floating body part 130 swings in the vertical direction, the weight of the first transmission part and the second transmission part 30b causes the vertical swing of the floating body part 130 and the movement of the first transmission part and the second transmission part. Since a phase difference can be generated between the vibration of the transmission portion 30b, the first transmission portion and the second transmission portion 30b can be relatively linearly moved (swayed like a so-called “spring pendulum”). ). Further, in the embodiment, the specific configuration of the spring portion 131 is such that the damping constant of the spring portion 131 is less than one. The detailed setting of the damping constant may be set based on, for example, experimental results, since it may differ depending on the weights of the first transmission section and the second transmission section 30b.

With the structure of the power generation system 400 as described above, even when the power generation system 400 is installed offshore, it is possible to obtain the vertical component force necessary for power generation. , a desired amount of power can be generated using the vertical force component.

(Configuration - function of power generation system)
The functions of the power generation system 400 configured in this way will be described.

First, for example, when a vertical component force of wave force is applied to the floating body portion 130, the first transmission portion and the second transmission portion 30b are pulled up by the spring portion 131. The transmission portion 30b relatively linearly moves upward. In this case, the first transmission portion and the first tooth portion 24 are pressed by the first tooth portion 24 of the pressing portion 20 to rotate in the power generation rotation direction (clockwise rotation direction). , the vertical component force is converted into a rotational force in the direction of power generation rotation (clockwise rotation direction). Then, the converted rotational force in the power generation rotation direction (clockwise rotation direction) is transmitted to the rotating shaft of the dynamo in the power generation section by the first transmission section via the first shaft 50, the belt, and the second shaft. Then, the rotating shaft of the dynamo is rotated by the transmitted rotational force, so that the dynamo can generate electricity.

Further, for example, when the vertical component force is no longer applied to the floating body portion 130 after the first transmission portion and the second transmission portion 30b move relatively linearly upward, the first transmission portion and the second transmission portion 30b As the weight of the second transmission portion 30b drops, the first transmission portion and the second transmission portion 30b relatively linearly move downward. In this case, the second transmission portion 30b is pressed by the second tooth portion 25 of the pressing portion 20 and rotationally moves in the power generation rotation direction (clockwise rotation direction). The portion 25 converts the self-gravity of the pressing portion 20 into a rotational force in the power generation rotation direction (clockwise rotation direction). Then, the converted rotational force in the power generation rotation direction (clockwise rotation direction) is transmitted to the rotating shaft of the dynamo in the power generation section by the second transmission section 30b via the first shaft 50, the belt, and the second shaft. Then, the rotating shaft of the dynamo rotates due to the transmitted rotational force, so that the dynamo can generate electricity.

(configuration - other configurations)
In addition to this, the power generation system 400 can be configured with any possible structure. Specifically, in Embodiment 5, the first transmission portion and the second transmission portion 30b are connected to the upper end portion of the floating body portion 130 via the spring portion 131 and the connection portion 134, and the pressing portion 20 is connected to the floating body portion. 130, but it is not limited to this. 26 to 28 are diagrams showing modifications of the power generation system 400 according to the fifth embodiment. For example, as shown in FIG. 26, the first transmission portion and the second transmission portion 30b are connected to the lower end portion of the floating body portion 130 via the spring portion 131 and the connecting portion 134, and the pressing portion 20 is connected to the upper end portion of the floating body portion 130. may be connected to Alternatively, as shown in FIG. 27, the first transmission portion and the second transmission portion 30b are connected to the right end portion of the floating body portion 130 via the spring portion 131 and the connection portion 134, and the pressing portion 20 is connected to the left end portion of the floating body portion 130. may be connected to Alternatively, as shown in FIG. 28, the first transmission portion and the second transmission portion 30b are connected to the right end portion of the floating body portion 130 via the spring portion 131 and the connection portion 134, and the pressing portion 20 is connected to the lower end portion of the floating body portion 130. may be connected to

Further, in Embodiment 5, the pressure portion 20, the first transmission portion, the second transmission portion 30b, the first shaft 50, the belt, the second shaft, the power generation portion, and the spring portion 131 are provided inside the floating body portion 130. Although it is explained that one set is accommodated, it is not limited to this. FIG. 29 is a diagram showing a modification of power generation system 400 according to Embodiment 5. In FIG. For example, as shown in FIG. 29, a plurality of sets may be provided. Also, as shown in FIG. 29, the connection positions of the first transmission portion, the second transmission portion 30b, and the pressing portion 20 of each set may be different, or may be the same connection position.

(effect)
As described above, according to Embodiment 5, when the movement direction of the relative linear movement is the vertical direction and the vertical component force is applied to the floating body portion 130, the spring portion 131 causes the first transmission portion and the second transmission portion 30b are pulled up, the first transmission portion and the second transmission portion 30b linearly move upward, which is one of the moving directions of the relative linear movement. Either one of the first transmission portion and the second transmission portion 30b is pressed by either the tooth portion 24 or the second tooth portion 25 to rotate. When the directional component force is no longer applied to the floating body portion 130, the first transmission portion and the second transmission portion 30b move relatively linearly as the weight of the first transmission portion and the second transmission portion 30b drop. By linearly moving downward, which is the other of the movement directions, the other of the first toothed portion 24 and the second toothed portion 25 can move the other of the first transmission portion and the second transmission portion 30b. Since the first transmission part, the second transmission part 30b, and the pressing part 20 are installed so that the power generation system 400 is installed in the offshore, the vertical direction necessary for power generation Since the force component can be obtained, a desired amount of power can be generated using the vertical component force, as in the power generation systems according to the third and fourth embodiments.

[Embodiment 6]
Next, Embodiment 6 will be described. This form is different from the third to fifth embodiments, and is a form of generating power using the vertical force component of wave force. Components that are substantially the same as those of the first embodiment are given the same reference numerals or names as used in the first embodiment, and the description thereof is omitted.

(composition)
First, the configuration of the power generation system according to Embodiment 6 will be described. FIG. 30 is a schematic diagram showing a power generation system according to Embodiment 6. FIG. As shown in FIG. 30, a power generation system 500 according to Embodiment 6 includes a first floating body portion 140, a pressing portion 20, a first transmission portion (not shown), a second transmission portion 30b, a first shaft 50, a belt (illustration omitted), a second shaft (illustration omitted), a power generation section (illustration omitted), a second floating body section 141, and a connection section 142.

(Configuration - first floating body section)
At least part of the first floating body part 140 can float on the water surface. The first floating body part 140 is formed of a substantially U-shaped hollow body. Specifically, as shown in FIG. one side), a second housing portion 140b (the other side of the substantially U-shaped vertical bar portion), and a third housing portion 140c (the substantially U-shaped horizontal bar portion).

The first housing portion 140a receives the vertical component force of the wave force while housing one of the two sets. The second housing portion 140b receives the vertical component of the wave force while housing the other of the two sets. As shown in FIG. 30, the first housing portion 140a and the second housing portion 140b are long hollow bodies made of, for example, metal material or resin material. is formed to Openings (not shown) are formed at the lower ends of the first housing portion 140a and the second housing portion 140b. The opening is an opening for taking the liquid (such as water) contained in the third containing portion 140c into the first containing portion 140a or the second containing portion 140b.

The third accommodation portion 140c is for connecting the first accommodation portion 140a and the second accommodation portion 140b. As shown in FIG. 30, the third accommodation portion 140c is a long tubular body made of, for example, a known stretchable member (an example of a resin material). Specifically, the third accommodation portion 140c The length in the longitudinal direction is set to approximately half the wavelength of the wave. Further, openings (not shown) are formed at both ends in the longitudinal direction of the third accommodating portion 140c. The opening is an opening through which the liquid (such as water) contained in the third containing portion 140c flows into or out of the first containing portion 140a or the second containing portion 140b.

The first floating body portion 140 may be formed by any method. At the same time, the other of the longitudinal ends of the third accommodation portion 140c and the lower end of the second accommodation portion 140b are connected by a fixture or the like, and the liquid is accommodated in the first floating body portion 140 before and after these connections. It is formed by

(Construction - pressing part)
As shown in FIG. 30, the pressing portion 20 includes a body portion 21 (excluding the third frame portion 21c). As shown in FIG. 30, the body portion 21 is arranged such that the longitudinal direction of the first frame portion 21a (or the second frame portion 21b) is substantially along the vertical direction, and the upper end portion of the body portion 21 is the first frame portion 21b. It is fixed to the upper end of the housing portion 140a or the second housing portion 140b by fasteners, welding, or the like.

(Construction-Second Floating Body Section)
At least a part of the second floating body part 141 can float on the water surface, and the connecting part 142 connects the first transmission part, the second transmission part 30b, and the first shaft. 50. The second floating body portion 141 is a substantially box-shaped body (for example, a rectangular parallelepiped) made of, for example, a metal material, a resin material, or a wooden material. It floats on the surface of the liquid contained in 140 so as to be able to swing vertically.

(Construction-Connector)
The connecting portion 142 connects the first and second transmitting portions 30b and the second floating body portion 141, and is formed of an elongated substantially rod-shaped body. Here, the method of connecting the first transmission portion and the second transmission portion 30b to the second floating body portion 141 by the connection portion 142 is arbitrary. After the portions 30b are spaced apart from each other and arranged side by side along the left-right direction, the first transmission portion and the second transmission portion 30b are fixed to the first shaft 50 by a fastener or the like. One of the longitudinal ends of the connecting portion 142 is connected to the first shaft 50 by a rotatable fixture or the like (for example, a ball bearing), and the longitudinal ends of the connecting portion 142 are connected to each other. is connected to the second floating body portion 141 by a fixture or the like.

With the structure of the power generation system 500 as described above, even when the power generation system 500 is installed offshore, it is possible to obtain the vertical component force necessary for power generation. , a desired amount of power can be generated using the vertical force component.

(Configuration - function of power generation system)
The functions of the power generation system 500 configured in this way will be described.

First, for example, when the vertical component force of the wave force is applied to either the first accommodation portion 140a or the second accommodation portion 140b of the first floating body portion 140, the first accommodation portion 140a and the second accommodation portion 140a While the third accommodation portion 140c of the first floating body portion 140 is deformed so that the level of the second floating body portion 141 accommodated in the portion 140b becomes substantially the same (accompanied by this deformation, the first accommodation portion 140a and the The distance between the second receiving portion 140b and the second receiving portion 140b is reduced), and the first transmitting portion and the second transmitting portion 30b received in either the first receiving portion 140a or the second receiving portion 140b move relatively linearly. relative linear movement toward the upward direction, which is one of the movement directions of . In this case, the first transmission portion and the first tooth portion 24 are pressed by the first tooth portion 24 of the pressing portion 20 to rotate in the power generation rotation direction (clockwise rotation direction). , the vertical component force is converted into a rotational force in the direction of power generation rotation (clockwise rotation direction). Then, the converted rotational force in the power generation rotation direction (clockwise rotation direction) is transmitted to the rotating shaft of the dynamo in the power generation section by the first transmission section via the first shaft 50, the belt, and the second shaft. Then, the rotating shaft of the dynamo is rotated by the transmitted rotational force, so that the dynamo can generate electricity.

Further, for example, after the first transmitting portion and the second transmitting portion 30b have relatively linearly moved upward, the vertical component force is applied to either the first accommodating portion 140a or the second accommodating portion 140b. When it is gone, while deforming the first floating body part 140 so that the levels of the second floating body part 141 housed in the first housing part 140a and the second housing part 140b are substantially the same (this deformation Accordingly, the distance between the first housing portion 140a and the second housing portion 140b returns to its original length), and the first transmission portion and the second transmission portion 30b relatively linearly moves downward. In this case, the second transmission portion 30b is pressed by the second tooth portion 25 of the pressing portion 20 and rotationally moves in the power generation rotation direction (clockwise rotation direction). The portion 25 converts the self-gravity of the pressing portion 20 into a rotational force in the power generation rotation direction (clockwise rotation direction). Then, the converted rotational force in the power generation rotation direction (clockwise rotation direction) is transmitted to the rotating shaft of the dynamo in the power generation section by the second transmission section 30b via the first shaft 50, the belt, and the second shaft. Then, the rotating shaft of the dynamo rotates due to the transmitted rotational force, so that the dynamo can generate electricity.

(configuration - other configurations)
In addition to this, the power generation system 500 can be configured with any possible structure. Specifically, in Embodiment 6, the first floating body portion 140 has been described as including the first housing portion 140a, the second housing portion 140b, and the third housing portion 140c, but the present invention is not limited to this. . FIG. 31 is a diagram showing a modification of power generation system 500 according to Embodiment 6. In FIG. For example, as shown in FIG. 31, the first floating body portion 140 may further comprise a vent opening 143. As shown in FIG. The ventilation openings 143 are openings for performing air intake or exhaust inside and outside the first floating body portion 140, and as shown in FIG. there is In this case, as a configuration for suppressing the inflow of water into the first floating body portion 140 through the ventilation opening 143, as shown in FIG. and near the upper end of each of the second receiving portions 140b. Also, a cover portion 144 that covers a part of the ventilation opening 143 from the outside may be provided in the vicinity of the ventilation opening 143 in each of the first accommodation portion 140a and the second accommodation portion 140b. With such a configuration, the relative linear movement of the first transmission portion and the second transmission portion 30b can be performed smoothly, and the power generation efficiency of the power generation system 500 can be improved.

Further, in Embodiment 6, the first floating body portion 140 is configured such that when the first transmission portion and the second transmission portion 30b move relatively linearly, the distance between the first accommodation portion 140a and the second accommodation portion 140b is reduced. Although it has been described that the distance is variable, it is not limited to this. 32 and 33 are diagrams showing modifications of the power generation system 500 according to the sixth embodiment. For example, as shown in FIG. 32, the first floating body section 140 may further include a communication section 145 that communicates the first housing portion 140a and the second housing portion 140b. The communicating portion 145 is an elongated tubular body, and is connected to each of the first housing portion 140a and the second housing portion 140b so as to communicate with the upper end portion thereof. Further, although the specific configuration of the communicating portion 145 is arbitrary, for example, both longitudinal end portions and their neighboring portions of the communicating portion 145 are made of an elastic material (for example, a resin material, etc.). Alternatively, the other portion may be made of a non-stretchable material (for example, a metal material, a resin material, or the like). In this case, although the specific configuration of the second housing portion 140b is arbitrary, it may be formed with substantially the same configuration as the communicating portion 145, for example. Alternatively, as shown in FIG. 33, the first floating body portion 140 may further include a pair of projecting portions 146 in addition to the ventilation opening portion 143 and the cover portion 144 described above. The pair of protrusions 146 are for maintaining the distance between the first accommodation portion 140a and the second accommodation portion 140b. As shown in FIG. 33, the pair of projecting portions 146 are arranged side by side with a gap in the vertical direction between the first housing portion 140a and the second housing portion 140b. It is connected to each of the first housing portion 140a and the second housing portion 140b by a rotatable fixture or the like (for example, a ball bearing or the like). With these configurations, when the first transmission portion and the second transmission portion 30b are relatively linearly moved, it is possible to suppress the variation in the distance between the first accommodation portion 140a and the second accommodation portion 140b. It is possible to adjust the amount of deformation of the third accommodation portion 140c.

Further, in Embodiment 6, the first floating body part 140 has been described as having the first housing portion 140a and the second housing portion 140b as the portions for housing the above set, but the present invention is not limited to this. FIG. 34 is a plan view showing a modification of the power generation system 500 according to Embodiment 6. FIG. For example, as shown in FIG. 34, the first floating body portion 140 may further include a fourth containing portion 140d and a containing cover portion 147. As shown in FIG. The fourth housing portion 140d is for housing the set, and is formed, for example, in substantially the same configuration as the first housing portion 140a, and is connected to the third housing portion 140c by a fastener or the like. ing. The accommodation cover portion 147 is for covering the first accommodation portion 140a, the second accommodation portion 140b, and the fourth accommodation portion 140d in order to improve the durability and weather resistance of the first floating body portion 140. It is connected to the first housing portion 140a, the second housing portion 140b, and the fourth housing portion 140d by fasteners or the like. With such a configuration, it is possible to increase the power generation amount of the power generation system 500 while maintaining the durability and weather resistance of the first floating body portion 140 .

Further, in Embodiment 6, it was explained that the power generation system 500 was installed offshore, but the present invention is not limited to this. FIG. 35 is a diagram showing a modification of power generation system 500 according to Embodiment 6. In FIG. For example, as shown in FIG. 35, the power generation system 500 may be installed near the wharf of a port, and may further include a collection unit 150. FIG. The collecting part 150 is a collecting means for collecting waves, and includes a first reflecting part 151 ( a first reflecting means) and a second reflecting portion 152 (second reflecting means) having a second paraboloid (in FIG. 35, a second paraboloid having an opening facing the land side); . As for the details of the configuration of the first reflecting portion 151 and the second reflecting portion 152, specifically, as shown in FIG. It is set larger than the diameter, and the first paraboloid and the second paraboloid face each other (more specifically, the focus of the first paraboloid and the focus of the second paraboloid are aligned), the first reflecting portion 151 and the second reflecting portion 152 are arranged. Further, regarding the details of the installation of the first floating body part 140, specifically, as shown in FIG. is arranged at a position where the focus of the first paraboloid and the focus of the second paraboloid coincide. With such a configuration, compared to the case of using waves other than the waves collected between the first reflecting section 151 and the second reflecting section 152, the first floating body section 140 is amplified by the mutual water level amplification. Since the first transmission portion or the second transmission portion 30b can be effectively pressed by the pressing portion 20 housed in the housing, the power generation amount of the power generation system 500 can be increased. In addition, by installing a plurality of collection units 150 that accommodate the first floating body units 140 near the quay, waves can be reduced (attenuated) by the collection units 150, so that waves around the harbor can be made calm. . Note that the collection unit 150 is not limited to being provided in the power generation system 500 according to the sixth embodiment, and may be provided in the power generation systems according to the first to fifth embodiments, for example.

(effect)
As described above, according to Embodiment 6, when the direction of relative linear movement is the vertical direction, the vertical component force of the wave force is applied to either the first accommodation portion 140a or the second accommodation portion 140b. In this case, while deforming the first floating body part 140 so that the levels of the second floating body part 141 housed in each of the first housing part 140a and the second housing part 140b are substantially the same, the first housing part 140 is deformed. When the first transmitting portion and the second transmitting portion 30b housed in either the portion 140a or the second housing portion 140b linearly move upward, which is one of the moving directions of the relative linear movement, Either the first transmission portion or the second transmission portion 30b is pressed by either the first tooth portion 24 or the second tooth portion 25 of the pressing portion 20 to rotate and move, and the first housing portion 140a or the After the first transmitting portion and the second transmitting portion 30b accommodated in one of the second accommodating portions 140b linearly move upward, the vertical component force is applied to one of the first accommodating portion 140a and the second accommodating portion 140b. , the first floating body portion 140 is deformed so that the level of the second floating body portion 141 housed in each of the first housing portion 140a and the second housing portion 140b becomes substantially the same. , the first transmission portion and the second transmission portion 30b move downward, which is the other of the moving directions of the relative linear movement, as the weight of the first transmission portion and the second transmission portion 30b drop. As a result, either the first transmission portion or the second transmission portion 30b is pressed by either the first tooth portion 24 or the second tooth portion 25 of the pressing portion 20 to rotate. Since the first transmission portion, the second transmission portion 30b, and the pressing portion 20 are installed as described above, for example, even when the power generation system 500 is installed offshore, it is possible to obtain the vertical component force necessary for power generation. Therefore, as in the power generation systems according to Embodiments 3 to 5, it is possible to generate a desired amount of power using the vertical force component.

[III] Modifications to the Embodiments Although the embodiments according to the present invention have been described above, specific configurations and means of the present invention are within the scope of the technical ideas of each invention described in the claims. In can be optionally modified and improved. Such modifications will be described below.

(Problem to be solved and effect of invention)
First, the problems to be solved by the invention and the effects of the invention are not limited to the above-described contents, and the present invention solves problems not described above or achieves effects not described above. and may solve only part of the problems described or provide only part of the advantages described. For example, even if the installability of the power generation system according to the present invention is about the same as the conventional one, if the same level of installability as the conventional one can be secured by a structure different from the conventional one, the problem of the present application is solved. .

(Regarding shapes, numbers, structures, and time series)
Regarding the components illustrated in the embodiments and drawings, the shape, numerical value, structure of multiple components, or interrelationships in chronological order may be arbitrarily modified and improved within the scope of the technical idea of the present invention. can be done.

(About the power generation system)
In Embodiments 1 and 2 above, the power generation system has been described as including a housing, but the present invention is not limited to this. For example, if the receiving portion is installed on an inclined portion of the installation surface so that the pressing portion 20 can move relatively linearly, the accommodating portion may be omitted.

Further, in the first to sixth embodiments, the power generation system has been described as including the belt and the second shaft, but the present invention is not limited to this. 2 shafts may be omitted. In this case, the power generation section is arranged near the first shaft, and a part of the first shaft is inserted through an insertion hole (not shown) formed in the side wall of the power generation section housing. It is housed inside, and the part of the housed is fixed to the rotation shaft of the dynamo by means of fixtures or the like.

Further, in the third embodiment described above, the power generation system 200 includes the pressing portion 20, the first transmission portion, and the second transmission portion 30b according to the first embodiment. Instead of these, the pressing portion 20 and the transmission portion 90 according to Embodiment 2 may be provided (the same applies to Embodiments 4 to 6 above).

(Regarding the first shaft)
In Embodiments 1 to 6 above, it was explained that the first shaft transmits the rotational force transmitted from the first transmission portion or the second transmission portion to the belt, but the present invention is not limited to this. For example, by providing a known speed change mechanism (eg, a gear box, etc.) on the first shaft, the torque transmitted from the first transmission portion or the second transmission portion is amplified by the known speed change mechanism, and then the amplification is performed. The resulting rotational force may be transmitted to the belt (the same applies to the second shaft).

(About the power generation section)
In Embodiments 1 to 6 described above, the power generation section is provided with a dynamo, but the present invention is not limited to this. For example, instead of the dynamo, a piezoelectric element may be provided. In this case, a pressing portion 20 for pressing the piezoelectric element is attached to the rotating shaft connected to the first shaft, and the piezoelectric element is pressed by the pressing portion 20 as the rotating shaft rotates. By fixing the piezoelectric element to the housing, it is possible to generate power.

(Regarding the receiving part)
In Embodiments 1 and 2 above, the receiving portion is formed of an elongated block-shaped body, but the present invention is not limited to this. For example, the front portion of the receiving portion protrudes rearward. It may be formed by a spherical body formed in a concave shape. Alternatively, the entire receiving portion may be formed in a parabolic shape that is concave and protrudes rearward.

Further, in the first and second embodiments described above, the front portion of the receiving portion is formed in a concave shape, but the present invention is not limited to this. For example, the receiving portion may be formed using a known valve structure so that wave water can reliably flow in and out in accordance with the direction of relative linear movement of the pressing portion 20 . Alternatively, the front portion of the receiver may be formed flat to facilitate manufacturability of the receiver. Further, in the first and second embodiments, the return portion and the moving portion are provided at the lower end portion of the receiving portion. , at least part of the return portion or the moving portion may be omitted.

(Appendix 1)
The power generation system of Supplementary Note 1 is a power generation system that converts an external force into electricity via a power generation means, the power generation means having a rotating shaft that rotates only in a power generation rotation direction that is one direction of rotation in which power can be generated; and a rotational force conversion means for converting the external force into a rotational force in the power generation rotation direction and transmitting the converted rotational force to the power generation means, wherein the rotational force conversion means rotates itself to a transmission means for transmitting the rotational force to the power generation means; and a pressing means for pressing the transmission means so that the transmission means is rotatably movable; A first transmission means that is rotatable only in the same direction as the rotation direction, and a second transmission means that is spaced apart from the first transmission means and is rotatable only in the same direction as the power generation rotation direction. 2 transmission means, wherein the pressing means, the first transmission means, or the second transmission means is provided in a virtual plane orthogonal to the rotation center axis of each of the first transmission means and the second transmission means When the external force is applied to the means, the first transmission means, the second transmission means, and the pressing means move relatively linearly along the imaginary plane. The pressing means is formed so that either one of the transmission means and the second transmission means is pressed to rotate, and the power generation means is arranged such that the relative linear movement is in one direction of the linear movement. In the case of the movement toward the When moving toward , power generation is performed by rotating the rotating shaft by the rotating force transmitted by the second transmitting means.

Further, the power generation system according to Appendix 2 is the power generation system according to Appendix 1, wherein the pressing means is a first tooth portion provided along the moving direction of the relative linear movement, and the first transmission a first tooth disposed in contact with the means; and a second tooth provided along the direction of movement of the relative linear movement at a position spaced from the first tooth, wherein the and a second tooth arranged so as to be in contact with the second transmission means, wherein the first tooth when the relative linear movement is movement toward one direction of the linear movement. When the first transmission means is pressed by and rotates in the power generation rotation direction, and the relative linear movement is movement in the other movement direction of the linear movement, the second tooth portion causes The first toothed portion and the second toothed portion are formed so that the second transmission means is pressed to rotate in the power generation rotation direction.

Further, the power generation system according to Supplementary Note 3 is the power generation system according to Supplementary Note 2, wherein the transmission means is a third transmission means spaced apart from each of the first transmission means and the second transmission means. A third transmission means rotatable only in the same direction as the power generation rotation direction, and a fourth transmission means provided so as to be in contact with the third transmission means, wherein rotation of the fourth transmission means a fourth transmission means for rotating the third transmission means accordingly, wherein the pressing means is a third tooth portion provided along the moving direction of the relative linear movement, A third tooth portion arranged to be in contact with the fourth transmission means is provided, and when the pressing means rotates toward one of the rotation directions in the in-plane rotation of the virtual plane, the first tooth portion and the The first transmission means and the second transmission means are pressed by the second tooth portion to rotate in the power generation rotation direction, and the pressing means rotates in the other rotation direction of the in-plane rotation of the virtual plane. In this case, the first tooth portion, the second tooth portion, and the third tooth portion was formed.

Further, the power generation system according to Appendix 4 is the power generation system according to Appendix 2 or 3, wherein the external force is a wave force, and the pressing means includes a main body portion having the first tooth portion and the second tooth portion. a receiving portion located below the main body portion for receiving a horizontal component of the wave force; and a connecting portion connecting the main body portion and the receiving portion; When the movement direction of the relative linear movement is the vertical oblique direction, when the horizontal component force is applied to the receiving portion, the pressing means moves in one of the movement directions of the relative linear movement. Either the first transmission means or the second transmission means is pressed by either the first tooth portion or the second tooth portion by linearly moving in the oblique upward direction. When the horizontal component force is no longer applied to the receiving portion after the rotational movement of the pressing means and the linear movement of the pressing means in the oblique upward direction, the pressing means is moved to the above position as the weight of the pressing means drops. By linearly moving in the oblique downward direction, which is the other of the moving directions of the relative linear movement, the other of the first tooth portion and the second tooth portion causes the first transmission means or the The first transmission means, the second transmission means, and the pressing means are installed such that the other of the second transmission means is pressed to rotate.

Further, in the power generation system according to Supplementary Note 5, in the power generation system according to Supplementary Note 4, when the pressing means linearly moves in the upward oblique direction, wave water flows into the receiving portion, and the pressing means The receiving portion is formed so that the water that has flowed in flows out to the outside of the receiving portion when the is linearly moved in the downward oblique direction.

Further, in the power generation system according to appendix 6, in the power generation system according to appendix 4 or 5, there is a housing means for housing at least the receiving portion, wherein the wave can flow into and out of the housing means. provided with a containing means, wherein the internal shape of the containing means is adapted to enhance the relative linear movement of the pressing means by amplifying the water level inside the containing means by waves entering the interior of the containing means. formed into a shape that allows

Further, in the power generation system according to Appendix 7, in the power generation system according to Appendix 2 or 3, the external force is wave force, and at least a portion of the power generation system is a deformable first floating body portion that can float on the surface of the water. a first floating body portion formed of a substantially U-shaped hollow body so that liquid can be contained only in a part of the inside of the first floating body portion; a second floating body portion located below the second transmission means, the second floating body portion being able to float on the liquid contained in the first floating body portion; the first transmission means and the second transmission; a connecting portion for connecting means and the second floating body portion, wherein the first transmission means and the second transmission means are provided inside each of the pair of substantially U-shaped vertical rod portions of the first floating body portion means, the pressing means, the second floating body portion, and the connecting portion, and the moving direction of the relative linear movement is the vertical direction, the vertical component force of the wave force When applied to one of the rod portions, the pair of vertical rod portions is deformed while the first floating body portion is deformed so that the level of the second floating body portion accommodated in each of the pair of vertical rod portions becomes substantially the same. When the first transmission means and the second transmission means accommodated in one of the vertical rod portions of the linearly move upward, which is one of the moving directions of the relative linear movement, the Either the first transmission means or the second transmission means is pressed by either the first tooth portion or the second tooth portion of the pressing means to rotate and move, and one of the pair of vertical rod portions is rotated. When the vertical component force is no longer applied to one of the pair of vertical rod portions after the first transmission means and the second transmission means accommodated in the pair of While deforming the first floating body part so that the level of the second floating body part accommodated in each of the vertical bar parts becomes substantially the same, the weight of the first transmission means and the second transmission means are lowered By linearly moving the first transmission means and the second transmission means in the downward direction, which is the other of the moving directions of the relative linear movement, the first tooth portion of the pressing means or The first transmission means, the second transmission means, and the pressing are arranged such that either one of the first transmission means or the second transmission means is pressed by either one of the second tooth portions to rotate. installed the means.

Further, the power generation system of Appendix 8 is the power generation system according to any one of Appendixes 1 to 7, further comprising collecting means for collecting waves, the collecting means having a first parabolic surface. Reflecting means and second reflecting means having a second paraboloid, wherein the opening diameter of the first paraboloid is larger than the opening diameter of the second paraboloid, and the first paraboloid The first reflecting means and the second reflecting means are arranged so that the surface and the second paraboloid face each other, and the distance between the first paraboloid and the second paraboloid is arranged. By using the wave force of the waves collected in the second stage, the pressing means presses either the first transmission means or the second transmission means to be rotationally movable.

Further, the power generation system of Appendix 9 is the power generation system according to any one of Appendixes 1 to 8, wherein either the first transmission means or the second transmission means is the first transmission means or the second transmission means. The first transmission means or the second transmission means are formed to rotate at a lower speed or a higher speed than either one of the transmission means.

(Effect of Supplementary Note)
According to the power generation system described in Supplementary Note 1, the pressing means, the first transmission means, or the second transmission means, within the imaginary plane perpendicular to the rotation center axis of each of the first transmission means and the second transmission means When an external force is applied to the means, the first transmission means, the second transmission means, and the pressing means move relatively linearly along the imaginary plane, thereby causing the pressing means to move the first transmission means. Alternatively, the pressing means is formed so that either one of the second transmission means is pressed to rotate, and the relative linear movement of the power generation means is a movement in one direction of the linear movement. , the rotation shaft is rotated by the rotational force transmitted by the first transmission means to generate power, and the relative linear movement is movement in the other movement direction of the linear movement In addition, since power is generated by rotating the rotating shaft by the torque transmitted by the second transmission means, the first transmission means and the second transmission means are parts distributed on the market (for example, ratchet gear etc.) , and there is no need to configure it with a special structure, so it is possible to improve the manufacturability of the power generation system and reduce the manufacturing cost.

According to the power generation system described in Appendix 2, when the relative linear movement is movement in one movement direction of the linear movement, the first transmission means is pressed by the first tooth portion to generate power. Rotational movement in the direction of rotation, and when the relative linear movement is movement in the other movement direction of the linear movement, the second transmission means is pressed by the second tooth portion to rotate in the power generation rotation direction. Since the first toothed portion and the second toothed portion are formed so as to move, when the pressing means moves relatively linearly, the first transmission is performed by the pressing means regardless of the moving direction of the relative linear movement. Since either the means or the second transmission means can be pressed so as to rotate in the power generation rotation direction, it is possible to reliably generate power.

According to the power generation system described in Supplementary Note 3, when the pressing means rotates toward one of the rotation directions in the in-plane rotation of the virtual plane, the first transmission means and the second transmission means are rotated by the first tooth portion and the second tooth portion. When the 2 transmission means is pressed and rotates in the power generation rotation direction, and the pressing means rotates in the other rotational direction of the in-plane rotation of the virtual plane, Since the first tooth portion, the second tooth portion, and the third tooth portion are formed so that the third transmission means is pressed to rotate in the power generation rotation direction, the rotation direction in the in-plane rotation of the virtual plane Regardless, when the pressing means rotates, the pressing means can press the first transmission means, the second transmission means, or the third transmission means so as to rotate in the power generation rotation direction. As a result, compared to the case where the third transmission means, the fourth transmission means, and the third tooth means are not provided, power generation can be performed regardless of the in-plane rotation of the imaginary plane of the pressing means. You can increase the amount.

According to the power generation system described in appendix 4, when the moving direction of the relative linear movement is the vertical oblique direction, when a horizontal component force is applied to the receiving portion, the pressing means is moved obliquely upward. When the transmitting means is pressed by the main body portion to move linearly in the upward direction, and the horizontal component force is no longer applied to the receiving portion after the pressing means linearly moves in the oblique upward direction, The transmitting means and the pressing means are installed so that the transmitting means is pressed by the main body portion and rotates when the pressing means moves linearly in an oblique downward direction as the pressing means drops its own weight. Therefore, when the pressing means moves relatively linearly in the vertical and oblique directions, it is possible to generate power using the wave force and the weight of the pressing means. , the power generation system can reliably generate power regardless of the direction of relative linear movement.

According to the power generation system described in appendix 5, when the pressing means linearly moves in the upward oblique direction, wave water flows into the receiving portion, and when the pressing means linearly moves in the downward oblique direction Since the receiving portion is formed so that the water that flows into the receiving portion flows out of the receiving portion, the weight of the water that has flowed into the receiving portion causes the pressing means to relatively move downward in a straight line. As compared with the case where the receiving portion is formed so that wave water does not flow into the receiving portion, relative linear movement of the pressing means can be reliably performed.

According to the power generation system described in appendix 6, the internal shape of the containing means is such that the waves flowing into the containing means amplify the internal water level of the containing means, thereby promoting the relative linear movement of the pressing means. As compared with the case where the internal shape of the containing means is made uniform, the internal water level of the containing means can be amplified when waves flow into the containing means. , the water level inside the containing means can be rapidly lowered when the inflowing waves flow out of the containing means. Therefore, the relative linear movement of the pressing means can be effectively performed, and the power generation amount of the power generation system can be increased.

According to the power generation system described in Supplementary Note 7, when the direction of relative linear movement is the vertical direction and the vertical component force of the wave force is applied to one of the pair of vertical rod portions, The first transmission means housed in one of the pair of vertical rod portions while deforming the first floating body portion so that the levels of the second floating body portions housed in each of the pair of vertical rod portions become substantially the same. and the second transmission means linearly moves upward, which is one of the moving directions of the relative linear movement, so that either the first tooth portion or the second tooth portion of the pressing means Either one of the first transmission means and the second transmission means is pressed and rotated, and the first transmission means and the second transmission means accommodated in one of the pair of vertical rod portions linearly move upward. When the vertical component force is no longer applied to one of the pair of vertical bar portions after the above, the second floating body portion accommodated in each of the pair of vertical bar portions has substantially the same level. 1 While deforming the floating body portion, the first transmission means and the second transmission means move in the other of the moving directions of relative linear movement as the first transmission means and the second transmission means drop their own weights. By linearly moving downward, either the first transmission means or the second transmission means is pressed by either the first tooth portion or the second tooth portion of the pressing means to rotate. Since the first transmission means, the second transmission means, and the pressing means are installed so as to move, for example, even when the power generation system is installed offshore, it is possible to obtain the vertical component force necessary for power generation. Therefore, it is possible to generate a desired amount of power using the vertical force component.

According to the power generation system described in Appendix 8, the opening diameter of the first paraboloid is larger than the opening diameter of the second paraboloid, and the first paraboloid and the second paraboloid face each other. The first reflecting means and the second reflecting means are arranged such that the force of the waves collected between the first and second paraboloids is used to generate the first reflection means by the pressing means. Since either one of the transmission means and the second transmission means is pressed to be able to rotate, compared to the case where waves other than the waves collected between the two are used, the pressure means is amplified by the water level between the two. It is possible to effectively press the first transmission means or the second transmission means by , and it is possible to increase the power generation amount of the power generation system.

According to the power generation system described in Appendix 9, one of the first transmission means and the second transmission means rotates at a lower speed or a higher speed than the other of the first transmission means and the second transmission means. Since the first transmission means or the second transmission means is formed, when the movement efficiency of the pressing means differs depending on the direction of relative linear movement of the pressing means, the first transmission means or the second transmission means By changing the rotation speed, it is possible to improve the movement efficiency of the pressing means, and to maintain the power generation efficiency of the power generation system.

Reference Signs List 1 power generation system 10 housing portion 11 first housing portion 12 second housing portion 13 opening 20 pressing portion 21 body portion 21a first frame portion 21b second frame portion 21c third frame portion 21d fourth frame portion 21e fifth frame portion 22 receiving portion 22a return portion 22b moving portion 23 connecting portion 24 first tooth portion 25 second tooth portion 26 projection portion 27 third tooth portion 28 accommodation hole 30a first transmission portion 30b second transmission portion 30c third transmission portion 30d 4 transmission part 40 projection part 50 first shaft 60 belt 70 second shaft 80 power generation part 81 housing 90 transmission part 91 projection part 100 power generation system 110 support frame part 110a first frame part 111 connecting bar 112 first floating body part 113 second 2 floating body part 114 tooth part 114a projection part 115 third floating body part 116 third tooth part 116a projection part 117 sway suppression part 118 anchor part 119 rope 120 first floating body part 121 main body of first floating body part 121a opening part 122 support part 123 barb Part 124 Second floating body part 125 Connection part 126 Wing part 127 Weight part 130 Floating body part 131 Spring part 132 Anchor part 133 Rope 134 Connection part 140 First floating body part 140a First accommodation part 140b Second accommodation part 140c Third accommodation part 140d Fourth accommodation portion 141 Second floating body portion 142 Connection portion 143 Ventilation opening 144 Cover portion 145 Communication portion 146 Projection portion 147 Accomodation cover portion 150 Collection portion 151 First reflection portion 152 Second reflection portion 200 Power generation system 300 Power generation system 400 Power generation system 500 Power generation system

Claims (2)

A power generation system that converts an external force into electricity via a power generation means,
a floating body part that is at least partially floatable on the surface of water, has a space inside the floating body part, and receives a component of the external force in a specific direction;
The power generation means, which is housed in the floating body and has a rotating shaft that rotates only in the power generation rotation direction, which is one direction of rotation in which power can be generated;
a rotational force conversion means that is housed in the floating body portion, converts the external force into a rotational force in the power generation rotation direction, and transmits the converted rotational force to the power generation means ;
The rotational force conversion means is
A spring portion connected to the floating body portion, wherein the spring portion expands and contracts due to a component force in a specific direction of the external force received by the floating body portion, causing the external force to rotate in the power generation rotation direction. a spring portion that can be converted into force;
A transmission means connected to the spring portion, and rotates itself while causing a phase difference between the oscillation of the floating body portion and the oscillation of the transmission means due to the weight of the transmission means, thereby generating the rotational force. to the power generating means; and
pressing means connected to the floating body portion for pressing the transmission means so that the transmission means can be rotated in accordance with the expansion and contraction of the spring portion;
disposing the spring portion outside the pressing means;
The spring portion and the pressing means are arranged side by side along the expansion and contraction direction of the spring portion,
power generation system. the force component in a specific direction of the external force is a vertical force component of the external force;
One of the ends of the spring portion in the direction of expansion and contraction is connected to one of the ends of the floating body portion in the vertical direction, and the other of the ends of the spring portion in the direction of expansion and contraction is connected to the transmission means. ,
One end of the pressing means is attached to the vertical end of the floating body so that the transmission means can swing substantially in the vertical direction as the spring section expands and contracts substantially in the vertical direction. connect to the other,
A plurality of sets each including the spring portion, the transmission means, the pressing means, and the power generation means are accommodated in the floating body portion,
Among the plurality of sets, the direction of expansion and contraction of the spring portions in some of the sets is different from the direction of expansion and contraction of the spring portions in the other portion of the sets,
The power generation system according to claim 1.

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