JP2018504558A - Resistor plate structure of energy generator - Google Patents

Abstract

According to a feature of the present invention, a housing having a power generation device therein, a rotating body rotatably coupled to the housing, and an outer peripheral surface of the rotating body coupled to the rotating body integrally with the housing And a rotation support base that is rotated around the center, and is formed in a plate shape, and a fixed groove is formed inside the one side surface, and the rotation support base is rotatably inserted therein, and generates resistance by gas or fluid. The resistance plate is in a vertical state so that resistance is generated in the forward direction in which the gas or fluid moves, and the resistance plate is in a horizontal state so that resistance is not generated in the reverse direction. And an angle limiting unit that is coupled so as to limit a rotation angle width of the resistance plate, and the rotating body is rotated by a resistance force generated by the resistance plate. And The power plant to the power generation energy by the rotational force of the rotating body to be rolling. According to the above-described present invention, the resistance plate structure of the energy generating device can be configured such that the rotating body is rotated by the resistance force generated by the resistance plate, and the power generation device can generate energy by the rotational force of the rotating rotating body. Can be provided.

Description

  The present invention relates to a resistance plate structure of an energy generating device, and more specifically, enables electric power generation by moving a rotating body by rotating a rotating body with resistance generated by the resistance plate of the energy generating device. The present invention relates to a resistance plate structure of an energy generator.

  In general, as a method for producing electricity, hydroelectric power generation, tidal power generation, thermal power generation, nuclear power generation, wind power generation, solar power generation, and the like are used. Among them, in the case of thermal power generation and nuclear power generation facilities, not only enormous energy consumption and advanced technology, human power and expensive advanced equipment are required for operation, but also installation and maintenance costs are considerable. Of course, there is a problem that there exists a reverse function that produces a large amount of environmental pollutants that are particularly fatal to the environment.

  Therefore, in consideration of the geographical conditions in South Korea where the three sides are surrounded by the sea and the mountainous area with good wind mobility is rich, it is friendly to the environment using wind power or tidal power, and low-carbon new renewable green energy Shows great interest in development.

  On the other hand, the most common wind turbine installed / used so far is a propeller type rotation, where a power transmission part is attached to the top end of one vertically installed prop, and about one side of the power transmission part One rotating wing in which three to four wings are arranged in a constant equiangular radial shape within a predetermined diameter range is configured to be mounted vertically in the direction in which the wind blows. Since the conventional wind power generator having such a structure is an irrational structure in which only one rotary blade device is installed vertically at the upper end of the support like a fan blade, a small amount is generated by the rotational drive of the one rotary blade. Only the amount of power generation can be expected, and in order to increase the amount of power generation, it is necessary to increase the number of the above structures in a vastly large area, so compared to the huge installation place and investment cost The amount of power generated is limited.

  Conventionally, the fixed position is determined only by the force pushing the resistance plate depending on the flow of water, but there is a problem that it is difficult to use all the pushing force when the resistance plate is heavy.

  The object of the present invention devised to solve the above-described problems is that the resistance plate is in a vertical state and no resistance is generated in the reverse direction so that resistance is generated in the forward direction in which the gas or fluid moves. In this way, the rotating support base and the resistor plate are coupled so that the resistor plate is in a horizontal state, whereby the rotating body is rotated by the resistance force generated by the resistor plate, and the power generator is generated by the rotating force of the rotated rotating body An object of the present invention is to provide a resistance plate structure of an energy generator that can generate energy.

  In addition, the object of the present invention is to form a minimum resistance angle with a horizontal plane by locking the locking projection to the projecting portion when the resistance plate is in a horizontal state, whereby gas or fluid When the positive direction and the end face of the rotation support table face each other, resistance is generated by the minimum resistance angle, and the resistance plate is quickly and easily rotated around the rotating body to generate resistance in a vertical state. At the same time, an object of the present invention is to provide a resistance plate structure of an energy generating device capable of rotating a rotating body.

  In addition, an object of the present invention is to adjust the rotation angle width of the resistance plate according to the angle separated from both side surfaces of the protruding portion adjusted by the angle adjusting unit, and thereby the resistance plate is generated in a vertical state. It is possible to control the rotational speed of the rotating body by adjusting the force, to prevent overloading of the power generator, to facilitate maintenance management, and to reduce the cost of maintenance management. It is to provide a resistance plate structure.

  According to the features of the present invention for achieving the above-described object, a housing provided with a power generation device therein, a rotating body rotatably coupled to the housing, and an outer peripheral surface of the rotating body are coupled. A rotating support base that is rotated around the housing integrally with the rotating body, and is formed in a plate shape, and a fixed groove that is formed in one side and is rotatably inserted into the rotary support base is formed. A resistance plate that generates resistance by gas or fluid, and a resistance plate that is vertical so that resistance is generated in the forward direction in which the gas or fluid moves, and a resistance plate that is horizontal so that resistance is not generated in the opposite direction The resistance plate is rotatably coupled to the rotation support base, and an angle limiting portion is coupled to limit the rotation angle width of the resistance plate, and the resistance force generated by the resistance plate Up Rotating body is rotated, the power generators to the power generation energy by the rotational force of the rotary body to be rotated.

  In addition, the angle limiting portion includes a protrusion formed on the outer peripheral surface of the rotation support base to form a first outer surface and a second outer surface, and one side of the inner peripheral surface of the fixing groove of the resistance plate. A separation groove formed on the outer side to have a radius larger than the radius of the fixing groove, a first locking protrusion and a second locking protrusion formed at both ends, and a protrusion of the rotation support base inserted therein. The resistor plate is rotated by the gas or fluid, and the locking projection of the separation groove is locked by the protrusion and the rotation is restricted, and the resistance plate is in a vertical state or a horizontal state depending on the moving direction of the gas or fluid. It becomes a state.

  Further, the separation groove of the resistance plate is formed such that an angle between the first locking projection and the second locking projection is greater than 90 ° and smaller than 180 °, and the first outer surface of the protruding portion is separated from the separation space. The first protruding jaw of the groove, the second outer surface of the protruding portion, and the second protruding jaw of the separation groove are formed in parallel to each other so that they can be brought into surface contact with each other by rotating the resistance plate. The resistance plate has a rotation angle between a vertical state and a horizontal state of less than 90 °, and when the resistance plate is in a horizontal state, the locking projection is locked to the protruding portion, so that a minimum resistance is provided between the resistance plate and the horizontal surface. When a corner is formed and the positive direction of the gas or fluid and the end face of the rotation support table are opposed to each other, a resistance is generated by the minimum resistance angle and rotated about the rotation support table to be in a vertical state. Become.

  In addition, the resistor plate has an upper resistor portion and a lower resistor portion that protrude upward and downward with respect to the fixed groove, and the protrusion length of the upper resistor portion and the lower resistor portion is one of two. One is formed longer, the lower resistor is formed heavier than the upper resistor, and the resistor plate resists when the rotating body is rotated in the positive direction that is the gas or fluid traveling direction. When the rotating body is rotated in the opposite direction, it is in a horizontal state so that no resistance is generated, and is not affected by the flow direction of gas or fluid.

  The resistor plate is formed with a coupling hole penetrating the fixing groove on the outer surface, and the rotation support base is recessed along an outer peripheral surface that is inserted into the fixing groove and faces the coupling hole. The locking groove is further formed, and further includes a detachment prevention pin that is inserted into the coupling hole and whose end is locked to the locking groove so that the rotation support base is not separated from the fixing groove.

  In addition, the resistance plate further includes an angle adjusting unit that is coupled to any one or more side surfaces of the projecting portions and is capable of adjusting an angle at which the projecting portions are separated from each other. The rotation angle width between the vertical state and the horizontal state is adjusted according to the angle separated from both sides of the protrusion, which is adjusted by the angle adjuster, and the angle adjuster is connected to one side of the protrusion. A length adjusting bar that is inserted and protruded outwardly is fixed, and is coupled to the outer peripheral surface of the length adjusting bar, and rotates the length adjusting bar on one side of the protruding portion. A rotation adjusting base that is inserted into a coupling hole of the resistance plate, and a rotation adjusting base that is inserted into a connection hole of the resistance plate. Including a shaft, the resistance plate is the length The length of the length adjusting bar that protrudes or is pulled outward from one side of the protrusion by the node member increases or decreases the separation distance between the one side of the protrusion and the angle adjusting member, thereby rotating the rotation. The width of the rotation angle rotated about the central axis is adjusted, the length adjusting bar is inserted and fixed to one side surface of the projecting portion by a screw coupling method, and the length adjusting member is the length adjusting bar. The length adjustment bar can be adjusted to be protruded or retracted to one side surface of the protrusion by rotating and connecting with a screw connection method.

  The rotation center shaft includes a first bearing on a rotation center shaft facing one side surface of the resistance plate, and a second bearing on a terminal portion of the rotation center shaft to smoothly rotate the resistance plate. The outer diameter of the first bearing is formed to correspond to the outer diameter of the protruding portion of the rotation center shaft, and the outer diameter of the second bearing is inserted into the fixing groove of the resistance plate. The first bearing provided at the intermediate portion is formed to correspond to the inner diameter of the fixed groove so as to be larger than the second bearing provided at the end portion.

  According to the above-described present invention, the resistance plate structure of the energy generating device can be configured such that the rotating body is rotated by the resistance force generated by the resistance plate, and the power generation device can generate energy by the rotational force of the rotating rotating body. Can be provided.

  In addition, according to the present invention, the resistance plate can be rotatably coupled to the support base of the various rotary support bases, and by adjusting the number, resistance due to fluid can be generated more, and the rotating body can be rotated. In addition, it is possible to provide a resistance plate structure of an energy generator that can further improve the amount of electric power generation.

1 is a perspective view showing a resistance plate structure of an energy generating device according to a preferred embodiment of the present invention.

1 is a perspective view showing a resistance plate of a resistance plate structure of an energy generating device according to a preferred embodiment of the present invention.

1 is an exploded perspective view showing a resistance plate of a resistance plate structure of an energy generating device according to a preferred embodiment of the present invention.

1 is a side view showing a resistance plate of a resistance plate structure of an energy generating device according to a preferred embodiment of the present invention.

  Advantages and features of the present invention and methods for achieving them will be clarified by embodiments described later in detail in conjunction with the accompanying drawings. However, the present invention is not limited to the embodiments disclosed below, but can be embodied in various forms different from each other. However, this embodiment is provided in order to make the disclosure of the present invention complete, and to fully inform the person of ordinary skill in the technical field to which the present invention belongs the scope of the invention. Defined only by the category of the term. Like reference numerals refer to like elements throughout the specification.

  Hereinafter, the present invention will be described with reference to the drawings for explaining a resistance plate structure of an energy generating device through an embodiment of the present invention.

  FIG. 1 is a perspective view illustrating a resistor plate structure of an energy generating device according to a preferred embodiment of the present invention, and FIG. 2 is a perspective view illustrating a resistor plate of the resistor plate structure of an energy generating device according to a preferred embodiment of the present invention. 3 is an exploded perspective view showing a resistor plate having a resistor plate structure of an energy generating device according to a preferred embodiment of the present invention. FIG. 4 is a diagram showing a resistor plate structure of an energy generating device according to a preferred embodiment of the present invention. It is the side view which showed the resistance board.

  First, the resistance plate structure of the energy generating device according to the present invention generates electricity by rotating along the fluid flow direction.

  1 to 4, the resistance plate structure of the energy generator according to the present invention includes a housing 110, a rotating body 120, a rotation support 130, a resistance plate 140, and an angle limiter 150.

  The housing 110 includes a power generation device inside.

  The rotating body 120 is rotatably coupled to the housing 110.

  The rotation support base 130 is inserted into the fixed groove 141 to form a locking groove 131 that is recessed along the outer surface facing the coupling hole 144.

  The resistance plate 140 is formed on one side to form a fixed groove 141 into which the rotation support base 130 is rotatably inserted, and generates resistance by gas or fluid.

  That is, the resistance plate structure of the energy generating device according to the present invention is such that the rotating body 120 is rotated by the resistance force generated by the resistance plate 140, and the power generation device generates energy by the rotating force of the rotating rotating body 120. it can.

  The rotation support base 130 includes a first bearing 132 and a second bearing 133.

  The first bearing 132 is provided on the rotation support base 130 facing one side surface of the resistance plate 140.

  The second bearing 133 is provided at the end of the rotation support base 130.

  That is, since the first bearing 132 and the second bearing 133 are provided on the rotation support base 130, the resistance plate 140 rotates smoothly.

  At this time, the first bearing 132 provided at the intermediate portion is larger than the second bearing 133 provided at the end portion.

  More preferably, the outer diameter of the first bearing 132 is formed to be the same as the outer diameter of the protrusion 151 of the rotation support base 130, and the outer diameter of the second bearing 133 is inserted into the fixing groove 141 of the resistance plate 140. It is preferable that the fixing groove 141 has the same inner diameter as possible.

  At this time, a plurality of resistance plates 140 may be provided on the rotation support base 130.

  Meanwhile, the angle limiting unit 150 is configured such that the resistance plate 140 is in a vertical state so that resistance is generated in the forward direction in which the gas or fluid moves, and the resistance plate 140 is in a horizontal state so that resistance is not generated in the reverse direction. The resistor plate 140 is rotatably coupled to the rotation support base 130, but is coupled so that the rotation angle width of the resistor plate 140 is limited.

  The angle limiting unit 150 includes a protrusion 151 and a separation groove 153.

  The protrusion 151 is formed to protrude from the outer peripheral surface of the rotation support base 130. At this time, the upper side outer surface of the protrusion 151 is referred to as a first outer surface, and the lower side outer surface is referred to as a second outer surface.

  The separation groove 153 is formed on the outer side so that one side of the inner peripheral surface of the fixing groove 141 has a radius larger than the radius of the fixing groove 141, locking protrusions 152 are formed at both ends, and the protruding portion 151 is inserted. At this time, the locking protrusion 152 formed on the upper side of the separation groove 153 is referred to as a first locking protrusion, and the locking protrusion 152 formed on the lower side is referred to as a second locking protrusion.

  That is, when the resistance plate 140 is rotated by gas or fluid, the locking protrusion 152 of the separation groove 153 is locked by the protrusion 151 and the rotation is restricted, and the resistance plate 140 becomes vertical or horizontal depending on the moving direction of the gas or fluid. .

  In other words, if the resistance plate 140 is in a vertical state, the first outer surface of the protrusion 151 and the first locking protrusion of the separation groove 153 are in contact with each other, and the resistance plate 140 is in a horizontal state. If so, the second outer surface of the protrusion 151 and the second locking projection of the separation groove 153 are in contact with each other.

  At this time, the separation groove 153 of the resistance plate 140 is preferably formed such that the locking projection 152 is larger than 90 ° and smaller than 180 °.

  In addition, the outer surface of the protrusion 151 of the rotation support base 130 and the inner surface of the separation groove 153 of the resistance plate 140 are formed in parallel to each other so that they can be brought into surface contact with each other when the resistance plate 140 is rotated. The

  As a result, when the resistance plate 140 is in the horizontal state when the rotation angle between the vertical state and the horizontal state is smaller than 90 °, the second locking protrusion 152 is locked to the second outer surface of the protruding portion 151. As a result, a minimum resistance angle is formed with the horizontal plane, and if the positive direction of gas or fluid and the end face of the rotary support 130 are in opposition, resistance is generated by the minimum resistance angle and the rotating body 120 is centered. Rotate to the vertical state.

  In addition, the resistor plate 140 is formed in a plate shape, the outer surface of the portion where the fixing groove 141 is formed protrudes, and the upper resistor portion 142 and the lower resistor portion 143 protruding upward and downward with respect to the fixing groove 141 are formed. It is formed.

  At this time, one of the upper resistor 142 and the lower resistor 143 has a longer length, and the upper resistor 142 and the lower resistor 143 have a lower weight than the upper resistor 142. It is preferable that 143 is formed to be heavier.

  More preferably, it is formed longer than the protruding length of the lower resistor 143, and the weight of the upper resistor 142 is further lighter than the weight of the lower resistor 143.

  That is, the resistance plate 140 is in a vertical state so that resistance is generated when the rotating body 120 is rotated in the forward direction that is the traveling direction of gas or fluid, and the rotating body 120 is rotated in the opposite direction. Then, it becomes horizontal so that no resistance is generated. In other words, the resistance plate 140 can be rotated around the rotation support base 130 sensitively to the flow direction of gas or fluid.

  In addition, the resistance plate 140 has a coupling hole 144 that penetrates the fixing groove 141 on the outer surface.

  At this time, the rotation support base 130 is inserted into the fixing groove 141 to form a locking groove 131 that is recessed along the outer surface facing the coupling hole 144.

  In addition, the resistor plate structure of the energy generating apparatus according to the present invention further includes a separation preventing pin 160.

  The detachment prevention pin 160 is inserted into the coupling hole 144 and the end thereof is locked in the locking groove 131 so that the rotation support base 130 is not separated from the fixed groove 141.

  That is, the resistance plate 140 is rotatably supported by the rotation support base 130 by gas or fluid, and at the same time, the resistance plate 140 is not separated from the rotation support base 130 by the separation preventing pin 160. When the resistance plate 140 is rotated, the end of the separation preventing pin 160 is rotated integrally with the resistance plate 140 along the locking groove 131 that is recessed along the outer surface.

  The resistance plate structure of the energy generating apparatus according to the present invention further includes an angle adjusting unit 170.

  The angle adjuster 170 is coupled to any one or more of both side surfaces of the protrusion 151 and can adjust the angle separated from both sides of the protrusion 151.

  In addition, a plurality of angle adjusting units 170 may be coupled to the first outer surface or the second outer surface of the protrusion 151.

  Accordingly, the rotational width of the resistance plate 140 between the vertical state and the horizontal state is adjusted according to the angle of the both sides of the protrusion 151 adjusted by the angle adjusting unit 170.

  The angle adjustment unit 170 includes a length adjustment bar 171, a length adjustment member 172, and an angle adjustment member 173.

  The length adjusting bar 171 is inserted into one side surface of the projecting portion 151 and is fixed so that the length projecting outward is adjustable.

  At this time, the length adjusting bar 171 is inserted and fixed to one side surface of the protruding portion 151 by a screw coupling method.

  The length adjusting member 172 is coupled to the outer peripheral surface of the length adjusting bar 171 and rotates to cause the length adjusting bar 171 to protrude outward from one side surface of the protruding portion 151 or to be retracted therein.

  At this time, the length adjusting member 172 is coupled to the length adjusting bar 171 by a screw coupling method, and the length adjusting bar 171 is adjusted to adjust the length by which the length adjusting bar 171 protrudes or is pulled into one side surface of the protrusion 151. Is possible.

  The angle adjusting member 173 is coupled to the end of the length adjusting bar 171.

  At this time, it is preferable that the outer surface of the angle adjusting member 173 and the locking projection 152 of the separation groove 153 of the resistance plate 140 face each other and be configured in parallel.

  That is, the resistance plate 140 has a length adjusting member 172 that protrudes or is pulled out of the first outer surface or the second outer surface of the protrusion 151 by the length of the length adjustment bar 171. As the separation distance between the second outer surface and the angle adjusting member 173 is increased or decreased, the width of the rotation angle rotated around the rotation support base 130 is adjusted.

  Therefore, the resistance plate structure of the energy generating device according to the present invention can control the rotational speed of the rotating body 120 by adjusting the resistance force generated when the resistance plate 140 is in a vertical state. Maintenance management is easy by preventing the load, and the cost of maintenance management can be reduced.

Those having ordinary knowledge in the technical field to which the present invention pertains should understand that the present invention can be implemented in other specific forms without changing the technical idea or essential features. is there. Thus, it should be understood that the above-described embodiments are illustrative in all aspects and not limiting. The scope of the present invention is defined by the scope of the claims from the above detailed description, and all modifications or variations derived from the meaning and scope of the claims and equivalents thereof are included in the scope of the present invention. Should be interpreted.

Claims (7)

A housing with a power generator inside,
A rotating body rotatably coupled to the housing;
A rotation support base coupled to the outer peripheral surface of the rotating body and rotated around the housing integrally with the rotating body;
A resistance plate that is formed in a plate shape, is formed inside on one side surface and is formed with a fixed groove into which the rotation support base is rotatably inserted, and generates resistance by gas or fluid;
The resistance plate is rotated so that the resistance plate is in a vertical state so that resistance is generated in the forward direction in which the gas or fluid moves, and the resistance plate is in a horizontal state so that resistance is not generated in the reverse direction. An angle limiter that is rotatably coupled to the resistor plate so that a rotation angle width of the resistance plate is limited,
A resistance plate structure of an energy generating device, wherein the rotating body is rotated by a resistance force generated by the resistance plate, and the power generation device generates energy by the rotating force of the rotating rotating body. The angle limiter is
A projecting portion projecting from the outer peripheral surface of the rotation support base to form a first outer surface and a second outer surface;
One end of the inner peripheral surface of the fixing groove of the resistance plate is formed on the outside so as to have a radius larger than the radius of the fixing groove, and a first locking protrusion and a second locking protrusion are formed at both ends, and the rotation support A separation groove into which the protrusion of the base is inserted,
When the resistance plate is rotated by the gas or the fluid, the locking projection of the separation groove is locked by the protrusion and the rotation is restricted, and the resistance plate is in a vertical state or a horizontal state depending on the moving direction of the gas or fluid. The resistance plate structure of the energy generator according to claim 1, wherein The separation groove of the resistance plate is formed such that an angle between the first locking protrusion and the second locking protrusion is larger than 90 ° and smaller than 180 °.
The first outer surface of the protrusion and the first protrusion jaw of the separation groove, and the second outer surface of the protrusion and the second protrusion jaw of the separation groove are brought into surface contact with each other as the resistance plate is rotated. The resistor plate is formed in parallel to each other so that when the resistor plate is in a vertical state and a horizontal state, the rotation angle is less than 90 °, and when the resistor plate is in a horizontal state, the locking protrusion is a protrusion. The minimum resistance angle is formed between the horizontal surface and the positive direction of the gas or fluid and the end surface of the rotation support table are opposed to each other, and resistance is generated by the minimum resistance angle. The resistance plate structure of the energy generating device according to claim 2, wherein the resistance plate structure is rotated about the rotation support base and is in a vertical state.   The resistor plate is formed with an upper resistor portion and a lower resistor portion protruding upward and downward with respect to the fixed groove, and the protrusion length of the upper resistor portion and the lower resistor portion is any one of two. The lower resistance part is formed heavier than the upper resistance part, and the resistance plate generates resistance when the rotating body is rotated in the positive direction that is the traveling direction of the gas or fluid. And a horizontal state so that no resistance is generated when the rotating body is rotated in the opposite direction, and is not affected by the flow direction of the gas or fluid. 2. A resistor plate structure of the energy generating device according to 1. The resistance plate is formed with a coupling hole penetrating the fixing groove on the outer surface,
The rotation support base is formed with a locking groove that is inserted into the fixed groove and is recessed along an outer peripheral surface facing the coupling hole, and the terminal is inserted into the coupling hole and the end is formed in the locking groove. The resistance plate structure of the energy generating device according to claim 1, further comprising a detachment prevention pin that is locked to prevent the rotation support base from being separated from the fixed groove. An angle adjustment unit that is coupled to at least one of the two side surfaces of the protrusion and is capable of adjusting an angle at which both sides of the protrusion are spaced apart;
In the resistance plate, a rotation angle width between a vertical state and a horizontal state is adjusted according to an angle separated from both side surfaces of the protrusion, which is adjusted by the angle adjustment unit,
The angle adjusting part is inserted into one side surface of the protruding part, and a length adjusting bar is fixed so that the length protruding outward is adjustable.
A length adjusting member that is coupled to the outer peripheral surface of the length adjusting bar and rotates the length adjusting bar so that the length adjusting bar protrudes to the outside of one side surface of the protruding portion or is pulled inside;
An angle adjustment member coupled to an end of the length adjustment bar,
The rotation support base includes a rotation center shaft that is inserted into the coupling hole of the resistance plate,
In the resistance plate, the length of the length adjusting bar that protrudes or is pulled outside the one side surface of the protruding portion by the length adjusting member increases the separation distance between the one side surface of the protruding portion and the angle adjusting member. The width of the rotation angle rotated around the rotation center axis is adjusted by narrowing,
The length adjustment bar is inserted and fixed to one side surface of the protrusion by a screw coupling method, and the length adjustment member is coupled to the length adjustment bar by a screw coupling method and rotated to rotate the length. The resistance plate structure of the energy generating device according to claim 2, wherein a length of the adjustment bar can be adjusted by being protruded or drawn into one side surface of the protrusion. The rotation center axis is provided with a first bearing on a rotation center axis facing one side of the resistance plate, and a second bearing is provided at an end portion of the rotation center axis to facilitate the rotation of the resistance plate.
The outer diameter of the first bearing is formed to be the same as the outer diameter of the protrusion of the rotation center shaft,
The outer diameter of the second bearing is formed to be the same as the inner diameter of the fixed groove so as to be inserted into the fixed groove of the resistance plate,
The resistance plate structure of the energy generating device according to claim 1, wherein the first bearing provided at the intermediate portion is larger than the second bearing provided at the end portion.

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