JP3242952U - Awning device for growing area - Google Patents

Abstract

An object of the present invention is to construct a simple and inexpensive device that automatically shields an organism growing area from direct sunlight when it is exposed to strong direct sunlight. A shield 106 provided movably from an upright open position OP to a shielding position for shielding an organism growing area from direct sunlight, and a block to stop at the open position by leaning the shield. a position SP, a stopper device 108 movable to a passing position that allows the shield to move to the shielding position by gravity, and sunlight positioned at a position shielded from the direct sunlight by the movement of the shield to the shielding position. An awning device 100 for a living-growing area characterized by including a power generation device 112 and an electric actuator 114 for moving a stopper device from a blocking position to a passing position by power from a solar power generation device. [Selection drawing] Fig. 1

Description

Applied mutatis mutandis to Article 30, Paragraph 2 of the Patent Law, which applies mutatis mutandis to Article 11 of the Utility Model Law 65th Tokyo Children's Invention Idea Exhibition Website (http://www.jiii.or.jp/tokyo/jido/2022/works/01.html) November 22, 2022

The present invention relates to a shade device that automatically covers an outdoor or indoor living area when the area is exposed to strong direct sunlight. Even indoors, the inside of a greenhouse such as a vinyl house or the window side is a technical field to which the present invention is applied because direct sunlight from the sun is incident thereon.

Organisms grown or cultivated outdoors require a certain amount of sunlight, but strong direct sunlight raises the temperature of the organisms themselves and the growing environment, leading to deterioration of the growing environment.
As the awning device, those shown in Patent Documents 1 to 7 have been proposed.
The invention disclosed in Patent Document 1 installs a solar panel on a rotating skylight and rotates the solar panel so that it always faces the direction of the sun. The solar panel always faces the sun. The skylight is not exposed to direct sunlight, so it can be expected to reduce the temperature rise in the room and to block direct sunlight.
In Patent Document 2, in order to more accurately control the opening and closing of the blinds installed on the windows of the building, the blind device is controlled based on shadow information indicating the direct sunlight irradiation condition of the building.
Patent Document 3 has a blind installed on a window on the outer wall of a building, an opening/closing history recording unit that records the opening/closing history of the manually operated blind, and a control device that controls and opens/closes the blind using the records of the opening/closing history recording unit.
In Patent Document 4, a space is formed in which the ceiling side or the ceiling side and the side side is open, and the other part is surrounded by a heat insulating surface made of soil or the like, and the opening of this space is covered with a light-transmitting heat insulating member.
Patent document 5 is an organism growth control apparatus characterized by using a solar battery as a power source for controlling tissue culture, germination, seedling raising, growth, flowering promotion, suppression, and preservation of organisms.
Patent Document 6 discloses an animal and plant growing apparatus having a container for growing animals and plants and an environment adjustment device for adjusting the environment in the container in order to reduce power supply from the outside and avoid an increase in the size of the device.

JP 2021-181720 JP 2017-96026 JP 2022-30695 Japanese Patent Laid-Open No. 5-211822 Japanese Patent Laid-Open No. 1-160477 JP 2001-136863

When the devices of Patent Literatures 1 to 6 are applied to the awning device for the organism growing area, there are the following problems.
In Patent Document 1, an effect of shielding direct sunlight can be expected, but a control program or the like is required, which complicates the device and cannot be adopted immediately.
Moreover, in Patent Documents 2 and 3, the subject and surrounding solar radiation conditions are computer-analyzed, and mainly indoor blinds are controlled, so there is the same problem as in Patent Document 1.
The invention of Patent Document 4 aims to control a series of growing environments in a closed system space, and uses a radiation prevention sheet.
The invention of Patent Document 5 uses a solar cell as a power source for tissue culture, germination, seedling raising, growth, flowering promotion, suppression, and preservation control of organisms, and has a problem that it cannot block direct sunlight.
The invention of Patent Document 6 uses permeable solar cells for the outer wall of an outdoor breeding facility to reduce the power supplied from the outside while maintaining the exhibition function, so there is a problem that sunlight cannot be shielded.

The object of the present invention is to solve the above-mentioned problems, and to provide a sunshade device for a creature-growing area that has a simple structure and is inexpensive, for automatically shielding the creature-cultivating area from direct sunlight when it is exposed to strong direct sunlight.

A first invention according to claim 1 is configured as follows.
a blocking position where the shield is rested at the open position by being leaned against; a stopper device movable to a passing position allowing the shield to move to the blocking position by gravity; a solar power generation device arranged at a position where the shield is shielded from the direct sunlight by moving the shield to the blocking position; electric power from the solar power generation device moves the stopper device from the blocking position to the passing position An awning device for a living-growing area, characterized in that it includes an electric actuator that allows

A second invention according to claim 2 is constructed as follows.
The stopper device includes a stopper housing, and a stopper that is slidable relative to the stopper housing and movable between the blocking position and the passing position.

A third invention according to claim 3 is configured as follows.
The awning device for the organism growing area according to the second invention is characterized in that the stopper is inclined so as to be positioned downward as it is separated from the shield.

A fourth invention according to claim 4 is constructed as follows.
The awning device for the creature growing area according to the second or third invention is characterized in that the electric actuator is a vibrating device that vibrates the stopper.

A fifth invention according to claim 5 is configured as follows.
The awning device for a creature growing area according to the fourth invention is characterized in that the electric actuator is a solenoid actuator that applies a force to move the stopper from the blocking position to the passing position (PP) side.

A sixth invention according to claim 6 is configured as follows.
The electric actuator includes a vibrating device for applying vibration to the stopper and a solenoid actuator for applying a force to move the stopper from the blocking position to the passing position, and the vibrating device is arranged on the opposite side of the stopper with the shield interposed therebetween.

A seventh device according to claim 7 is configured as follows.
The awning device for the creature growing area according to the first invention is characterized in that the shield is composed of a plurality of shields.

The eighth device according to claim 8 is configured as follows.
The shielding body is a sunshade device for the organism growing area according to the first or seventh invention, characterized in that an aluminum sheet is arranged on the surface of the shielding body.

In the awning device for the organism-cultivating area according to the present invention, the shield is provided movably from an upright open position to a shielding position that shields the organism-cultivating area from direct sunlight. When the photovoltaic power generation device receives direct sunlight, the generated electric power reaches a predetermined value or more, and the electric actuator operates to move the stopper device from the blocking position to the passing position. As a result, the shield cannot rest against the stopper device and thus moves to the shielding position. In the shielded position, the shield covers the growth area, thereby shielding the growth area from direct sunlight. In addition, since the shield shields the solar power generation device from sunlight, the solar power generation device stops power generation and substantially does not generate excessive power. Therefore, according to the present invention, it is possible to provide an awning device for a living-growing area with a simple structure and at a low cost. In addition, since the power source of the electric actuator is a photovoltaic power generation device and does not use an outlet port such as a commercial power source, there is an advantage that the degree of freedom of installation location is increased.

FIG. 2 is a perspective view of the shielding body of Embodiment 1 of the awning device for the organism growing area of the present invention in an open position; 1 is a perspective view of a state in which the shield of Embodiment 1 of the awning device for the creature growing area of the present proposal is positioned at the shielding position; FIG. FIG. 2 is an explanatory diagram of stopper 126 of Embodiment 1 of the awning device for the organism growing area of the present invention, where (A) is a front view, (B) is a cross-sectional view along line AA in (A), and (C) is. FIG. 10 is an explanatory view of a stopper 126 of Embodiment 2 of the awning device for the living thing growing area of the present invention, (A) is a front view, (B) is a cross-sectional view along the line BB in (A), and (C) is a perspective view of the vibration actuator. FIG. 10 is a perspective view for explaining the connection of electric actuators in Embodiment 2 of the awning device for the living thing growing area of the present invention. FIG. 3 is a perspective view of Embodiment 3 of the awning device for the living growth area of the present invention; FIG. 10 is an explanatory diagram of the shields in Embodiment 3 of the awning device for the living thing growing area of the present invention, (A) is a perspective view, (B) is a front view and left side view of the first shield, (C) is a front view and left side view of the second shield, and (D) is a front view and left side view of the third shield. It is explanatory drawing of the width adjustment apparatus in Embodiment 3 of the awning apparatus for the living thing breeding area|region of this invention, (A) is a front view, (B) is explanatory drawing. FIG. 11 is a front view of a state in which the shield of Embodiment 3 of the awning device for the creature growing area of the present invention is attached to the width adjusting device. FIG. 11 is a partial cross-sectional view of the vibration actuator of Embodiment 4 of the awning device for the living-growing area of the present invention;

An embodiment of a sunshade device for a living-growing area according to the present invention will be described below with reference to the accompanying drawings.

First, the awning device 100 for the organism growing area of Embodiment 1 will be described with reference to FIGS. 1 to 3. FIG.
The sunshade device 100 for the organism-growing area in Embodiment 1 is installed over the light-receiving opening 104 of the container 102, which is the organism-growing area, and has the function of quickly blocking the incoming direct sunlight when it enters the light-receiving opening 104.
The awning device 100 for the organism growing area of Embodiment 1 is composed of at least a shield 106, a stopper device 108, a solar power generation device 112, and an electric actuator 114. As shown in FIG.

First, the container 102 will be explained.
The container 102 has a function of housing an organism to be grown, for example, a water tank for growing fish, an insect cage for growing insects, a basin for growing aquatic plants, and a bowl for plants.
In Embodiment 1, the tank 116 for raising fish is formed into a cube by a first side wall 1161, a second side wall 1162, a third side wall 1163, a fourth side wall 1164, and a bottom wall 1165, and the light receiving opening 104 whose upper surface is a square opening.
Water is stored at a predetermined depth in the water tank 116, and a predetermined number of fish such as killifish are raised.

Next, the shield 106 will be explained.
A shield 106 is positioned relative to the light receiving aperture 104 and has the function of selectively opening or substantially shielding the light receiving aperture 104 .
In Embodiment 1, the shield 106 is a flat plate made of a lightweight material such as resin. The shield 106 is preferably an aluminum sheet placed on the surface of the heat insulating material. This is because shield 106 reflects sunlight and suppresses radiant heat directed toward water tank 116 .
The shield 106 is rotatably provided on a substrate 118 placed on the side wall of the water tank 116 .
The substrate 118 is formed in an L shape as a whole when viewed from above, and is composed of a first substrate portion 118A positioned over the entire length of one side of the rectangular frame of the water tank 116, which is the upper end of the fourth side wall 1164 in the first embodiment, a second substrate portion 118B connected to the first substrate portion 118A and placed on the upper surface of the third side wall 1163, and a third substrate portion 118C placed on the upper surface of the first side wall 1161. It is installed in a fixed state with respect to the water tank 116 by. However, it is not necessary to use fixing means.
A first bearing 122A is provided on the second substrate portion 118B, and a second bearing 122B is provided on the third substrate portion 118C. Ends of the rod-shaped rotating shaft 124 are supported by the first bearing 122A and the second bearing 122B, respectively, and provided parallel to the first substrate portion 118A. In other words, the pivot shaft 124 is arranged horizontally.
The shielding body 106 in Embodiment 1 can move between an open position OP in which it is substantially upright and a shielding position CP in a horizontal state, with the rotation shaft 124 as a support shaft. Specifically, the shield 106 can move by gravity from the open position OP to the shielded position CP. In other words, the shielding body 106 can be rotated from the open position OP to the shielding position CP by gravity using the rotating shaft 124 as a support shaft, and conversely can be rotated and moved from the shielding position CP to the open position OP.
At the open position OP, the shield 106 has a moment to rotate toward the light receiving aperture 104 due to its own weight, but it leans against the stop end 126E of the stopper 126 of the stopper device 108 located at the blocking position SP and is held at the open position OP.
When the stopper 126 moves to the passing position PP, the shield 106 can be rotated toward the light receiving opening 104 by its own weight.
At the shielding position CP, the shield 106 substantially covers the light-receiving aperture 104 and blocks incident sunlight from the light-receiving aperture 104 . In addition, the shield 106 substantially shields the solar power generation device 112 from direct sunlight at the shield position CP. In other words, when the shield 106 is positioned at the shielding position CP, the shield 106 is positioned above the solar power generation device 112 and blocks direct sunlight to the solar power generation device 112, so the solar power generation device 11 does not generate power.

Next, the stopper device 108 will be explained.
The stopper device 108 has a function of holding the shield 106 at the open position OP and enabling the movement of the shield 106 to the shielding position CP.
In Embodiment 1, the stopper device 108 includes a bar-shaped stopper 126, a stopper housing 128, and a solenoid actuator 136 as the electric actuator 114, as shown in FIG.

First, the stopper 126 will be explained.
The stopper 126 has a function of preventing the shield 106 from moving from the open position OP to the shield position CP and allowing the shield 106 to move to the shield position CP. In other words, it has a supporting function of supporting the shield 106 so that it does not fall due to its own weight, and a non-supporting function of not supporting the shield 106 . In Embodiment 1, the stopper 126 is configured by a rod. The cross-sectional shape of the bar may be rectangular, triangular, or the like, but preferably circular.
Since the stopper 126 constitutes an iron core 136F that is part of the solenoid actuator 136, the stopper 126 is preferably made of a magnetic metal such as iron.
The middle portion of the stopper 126 is preferably passed through a pipe 134 having a circular cross section and made of a non-magnetic material.
A movement restricting body 138 is preferably attached to the stopper 126 .

Next, stopper housing 128 will be described.
Stopper housing 128 has at least the function of movably holding stopper 126 . In Embodiment 1, the stopper housing 128 has a cubic shape, and the intermediate portion of the stopper 126 is slidably passed through a through hole 132 penetrating from the front surface 128F on the side of the light receiving opening 104 to the rear surface 128B on the opposite side.
Stopper housing 128 is fixed to the upper portion of support 142 erected from the upper surface of second substrate portion 118B, and held in an inclined state so that stopper 126 is positioned downward as it moves away from shield 106 . That is, the through hole 132 is obliquely fixed so as to be forwardly lowered from the side of the light receiving opening 104 toward the opposite side of the light receiving opening 104 . In other words, the central axis CL of the stopper 126 is configured to form a predetermined angle A with respect to the horizontal line HL. Angle A is preferably about 20 degrees.
An intermediate portion of the stopper 126 is slidably covered with a pipe 134 made of a non-magnetic material.
A coil 144 is formed by winding an electric wire around a portion of the outer periphery of the pipe 134 .
A solenoid actuator 136 is configured by the coil 144 and a part of the iron core 136F of the stopper 126. As shown in FIG.
By fixing the outer peripheral surface of the coil 144 to the inner wall of the through hole 132 , the intermediate portion of the stopper 126 is configured to be axially slidable with respect to the stopper housing 128 via the pipe 134 .
Since the through-hole 132 is obliquely configured, the stopper 126 penetrating through the through-hole 132 receives the force of gravity to move away from the light receiving opening 104, so that the stopper can be moved even when the output of the solenoid actuator 136 is small. However, the stopper 126 is preferably determined to remain stationary due to the frictional force between the pipes 134 when the coil 144 is not energized above a predetermined value.

Next, movement restrictor 138 will be described.
Movement restricting body 138 has a function of restricting the movement range of stopper 126 with respect to stopper housing 128 .
Movement restricting body 138 is composed of first movement restricting body 1381 and second movement restricting body 1382 .
The first movement restricting body 1381 is fixed to the surface 128F side of the stopper 126 and provided in a flange shape.
The second movement restricting body 1382 is fixed to the back surface 134B side of the stopper 126 and has a flange shape.
The first movement restricting body 1381 and the second movement restricting body 1382 are provided in a positional relationship that sandwiches the stopper housing 128 and is separated by a predetermined distance.
In other words, when the first movement restricting body 1381 is engaged with the surface 128F, the stop end 126E of the stopper 126 is positioned at the passing position PP out of the movement path of the shield 106, and the stopper 126 is prevented from coming off the stopper housing 128.
When the second movement restricting body 1382 is engaged with the rear surface 128B, the stop end 126E of the stopper 126 is positioned at the blocking position SP projecting into the movement path of the shield 106, and prevents the stopper 126 from falling off from the stopper housing 128.

Next, the photovoltaic power generation device 112 will be described.
The solar power generation device 112 is a so-called solar panel, and has a function of generating power using the photovoltaic effect of sunlight and outputting predetermined power. In Embodiment 1, the photovoltaic power generation device 112 is a commercially available inexpensive solar panel, and for example, a silicon solar cell module (1.5V 300mA) ETMP300-1.5V manufactured by Goldmaster & Everstep Development Limited can be used.
The photovoltaic power generation device 112 has a positive wire 112P and a negative wire 112N.
The solar power generation device 112 needs to generate electric power so that the solenoid actuator 136, which is the electric actuator 114, can move the stopper 126 in the direction of arrow D in FIG. The photovoltaic power generation device 112 may be composed of a single panel, or may be composed of a plurality of panels.

Next, the solenoid actuator 136 will be explained.
Solenoid actuator 136 has a function of generating a predetermined force in a predetermined direction on iron core 136F by using magnetic force generated by current flowing through coil 144 . In Embodiment 1, the solenoid actuator 136 is composed of the coil 144 and the iron core 136F that is part of the stopper 126. As shown in FIG. Therefore, in the solenoid actuator 136 of the first embodiment, when a DC power source is connected to the coil 144, a force is generated in the direction of the arrow D shown in FIG. 4(A) according to Fleming's left-hand rule, and the stopper 126 is moved in the same direction, thereby moving the stopper 126 to the passing position PP outside the movement path of the shield 106.
The force in the direction of arrow D is proportional to the magnitude of the magnetic flux generated in the coil 144, and the magnetic flux is determined by multiplying the inductance L of the coil 144 by the current I. Therefore, since the condition of the coil 144 does not change, the magnetic flux generated in the coil 144 generates a force of a predetermined value or more when a current of a predetermined value or more is supplied from the power output from the solar power generation device 112, and as a result, the stopper 126 is moved in the arrow D direction.

Next, connection between the solar power generation device 112 and the coil 144 of the solenoid actuator 136 will be described. Note that the solar power generation device 112 in Embodiment 1 will be described as a first solar power generation device 1121 for the sake of convenience in order to distinguish it from the solar power generation devices 112 in other embodiments.
The positive wire 112P and the negative wire 112N of the first photovoltaic power generation device 1121 are connected to the terminals of the coil 144 so that the force in the arrow D direction acts on the stopper 126 in the coil 144. This eliminates the need for a switch between the first photovoltaic power generator 1121 and the coil 144 .
A commercially available solar cell module, a so-called solar panel, can be used for the first solar power generation device 1121, and one or a plurality of solar panels can be connected in series or parallel to one electric actuator 114 and used.

Next, the operation of the first embodiment will be described.
First, the awning device 100 for the organism growing area is prepared. That is, the substrate 118 is placed on the first side wall 1161, the third side wall 1163, and the fourth side wall 1164. Next, after the shield 106 is rotated to the open position OP, the stopper 126 is moved toward the light receiving opening 104, and the second movement restricting body 1382 is brought into contact with the back surface 134B and positioned at the blocking position SP.
The preparation is then completed by having the shield 106 rest against the stop end 126E of the stopper 126. FIG. In this state, the water tank 116, which is the container 102, is installed so that the light receiving opening 104 faces the sun at a predetermined time.
When the sun moves and sunlight enters the light receiving aperture 104, in other words, when a predetermined amount of sunlight enters the first solar power generation device 1121, a predetermined electromotive force is generated in the first solar power generation device 1121, and electric power with a predetermined current and voltage is output to the coil 144. As a result, the coil 144 generates a predetermined magnetic force, and since a predetermined force acts on the stopper 126 in the direction of arrow D, it becomes greater than the frictional force between the stop end 126E and the shield 106, and the stopper 126 moves to the passing position PP.
By moving the stopper 126 to the passing position PP, the shield 106 moves to the shielding position CP by its own weight.
When the shield 106 moves to the shielding position CP, sunlight does not enter the first photovoltaic power generation device 1121, so that it does not generate electricity and substantially no power is output to the coil 144, so that an unexpected situation does not occur even if there is no switch means.

Next, Embodiment 2 will be described with reference to FIGS. 4 and 5. FIG.
In the second embodiment, the same reference numerals are assigned to the same parts as in the first embodiment, and the description thereof will be omitted, and the different configurations will be described.
Embodiment 2 is an example in which a plurality of electric actuators 114 are provided.
The electric actuator 114 in the second embodiment is an example of combining the solenoid actuator 136 in the first embodiment with the vibration actuator 152 .

Next, the vibration actuator 152 will be explained.
Vibration actuator 152 has a function of imparting vibration to shield 106 . In Embodiment 2, vibration actuator 152 is configured by vibration device 154 including a small vibration motor attached to stopper housing 128 and contact member 156 .

Vibration device 154 is composed of electric motor 158 , eccentric weight 162 , and rotor cover 164 .

The electric motor 158 has a small-diameter cylindrical shape, and the bottom wall is fixed to the tip of a rod-shaped support 168 that is partially penetrating a second through hole 166 formed in the stopper housing 128 . By fixing the electric motor 158 to the tip of the small-diameter rod-shaped support 168, the vibration of the electric motor 158 can be amplified.
The electric motor 158 is set to start rotating when an output (current x voltage) that is a predetermined amount less than the maximum output power of the second photovoltaic generator 1122 is applied. In other words, if the second photovoltaic power plant 1122 outputs a predetermined maximum power, the electric motor 158 will rotate.

The support 168 is arranged in parallel with the stopper 126 at a predetermined interval.
An eccentric weight 162 is fixed to the rotating shaft of the electric motor 158 . Thus, when the electric motor 158 rotates, the eccentric weight 162 will rotate and the electric motor 158 will vibrate.
The eccentric weight 162 is preferably covered with a bottomed cylindrical rotor cover 164 . Therefore, the electric motor 158, the eccentric weight 162, and the rotor cover 164 can be handled as a unit.

The contact body 156 is made of a flexible material, such as polyethylene terephthalate, in the shape of a thin hollow cube, and the vibrating device 154 is arranged inside.
The bottom of contact 156 is fixed to the top of support 168 . Thereby, the contact body 156 is vibrated together with the vibration device 154 .

One side wall 156W of the contact member 156 contacts the opposite surface of the shield member 106 when the shield member 106 rests against the stop end 126E of the stopper 126 and rests in the open position OP. Therefore, when the contact member 156 vibrates, the vibration can be transmitted to the shield 106 .
Due to the vibration of the shield 106, the stop end 126E and the shield 106 repeat contact and non-contact states microscopically, so that the frictional force between the stop end 126E and the shield 106 is reduced.
The electric motor 158 is connected to a second photovoltaic generator 1122 different from the solenoid actuator 136 via a positive wire 112P and a negative wire 112N. Similarly to the first solar power generation device 1121, the second solar power generation device 1122 is also shielded from sunlight by the shield 106 when the shield 106 moves to the shielding position CP. However, if one photovoltaic device 112 has sufficient power, it can be connected to the first photovoltaic device 1121 in common with the solenoid actuator 136 .

In the second embodiment, the magnetic flux acting on the stopper 126 in the solenoid actuator 136 does not have to be so large that the magnetic flux pulls the shield 106 against the stopper 126 to overcome the frictional force. This is because the vibration by vibration actuator 152 reduces the frictional force between shield 106 stop end 126E.

Next, the operation of the second embodiment will be described.
First, the shield 106 is prepared.
The shield 106 is moved from the shield position CP to the open position OP, and the shield 106 is leaned against the stop end 126E of the stopper 126 to be held at the open position OP. In this shielding position CP, one side wall 156W of the contact 156 is brought into contact with the opposite surface of the shield 106, causing vibrations of the vibrating device 154 and thus of the vibration actuator 152 to be transmitted to the shield 106 via the contact 156.
When the sunlight incident on the first photovoltaic power generation device 1121 and the second photovoltaic power generation device 1122 reaches a predetermined amount or more, the first photovoltaic power generation device 1121 and the second photovoltaic power generation device 1122 produce an output of a predetermined value or more. As a result, in the solenoid actuator 136, a predetermined force in the arrow D direction acts on the stopper 126. As shown in FIG. Also, the electric motor 158 in the vibration actuator 152 rotates, and the rotation of the eccentric weight 162 causes the vibration device 154 to vibrate. This causes the contact 156 to vibrate the shield 106 . Due to the vibration of the shield 106, the stop end 126E of the stopper 126 and the shield 106 are brought into contact with each other in a short cycle, and as a result the frictional resistance between the shield 106 and the stop end 126E is reduced. Therefore, even if the moving force by the solenoid actuator 136 is small, the stopper 126 can be moved.

As a modification of the second embodiment, the stopper 126 is arranged at an angle without the coil 144. When the stopper 126 is not in contact with the shield 106, the stopper 126 is allowed to tilt by its own weight. It can be configured to tilt by weight. In other words, the solenoid actuator 136 can be omitted.

Next, Embodiment 3 according to the present invention will be described with reference to FIGS. 6 to 8. FIG.
Embodiment 3 has the same configuration as Embodiment 2, but the shield 106 is composed of a plurality of shields, the size of the shield 106 can be adjusted according to the size of the light receiving opening 104 of the container 102, and the vibration actuator 152 has a different configuration. The same components as those in the second embodiment are denoted by the same reference numerals, descriptions thereof are omitted, and different configurations are described. The electric actuator 114 in Embodiment 3 is called a third electric actuator 1143, and the vibration actuator 152 is called a second vibration actuator 1522.

The shield 106 in Embodiment 3 is referred to as a third shield 306 for convenience.
The third shield 306 is composed of a plurality of shields, as shown in FIG. Specifically, the third shield 306 is composed of a 31st shield 3061 , a 32nd shield 3062 and a 33rd shield 3063 . The 31st shield 3061, the 32nd shield 3062, and the 33rd shield 3063 are all thin plates.

The 31st shield 3061 has a rectangular thin plate shape having a predetermined first height H1 and a first width W1, and is provided with a 31L bearing portion 3061L and a 31R bearing portion 3061R each having a circular shaft hole formed at the lower end thereof.

The 32nd shield 3062 has a rectangular thin plate shape with a predetermined first height H1 and a second width W2, and is provided with a 32L bearing portion 3062L and a 32R bearing portion 3062R each having a circular shaft hole formed at the lower end thereof, and a 32nd opening 3062o is formed between the 32L bearing portion 3062L and the 32R bearing portion 3062R. In Embodiment 3, the first height H1 of the 32nd shield 3062 is formed to be the same as the first height H1 of the 31st shield 3061, but they may be different. The second width W2 is configured to be a second width W2 different from the first width W1.

The 33rd shield 3063 is in the form of a rectangular thin plate having a predetermined second height H2 and a first width W1, and is provided with a 33L bearing portion 3063L and a 33R bearing portion 3063R each having a circular shaft hole formed at its lower end. In Embodiment 3, the 33rd shield 3063 is formed to have a second height H2 lower than the first height H1 of the 31st shield 3061, but they may be the same. The first width W1 in the thirty-third shield 3063 may be configured with different widths.

A first support shaft 3081 passes through the 31L bearing portion 3061L and the 31R bearing portion 3061R, a second support shaft 3082 is supported by the 32L bearing portion 3062L and the 32R bearing portion 3062R, and a third support shaft 3083 is rotatably and slidably supported by the 33L bearing portion 3063L and the 33R bearing portion 3063R. The first support shaft 3081, the second support shaft 3082, or the third support shaft 3083 is a round bar and constitutes a part of the width adjustment device 172.

The width adjusting device 172 will be explained.
The width adjuster 172 has the function of making the width of the third shield 306 adjustable.
The width adjuster 172 is composed of a first width adjuster 1721 and a second width adjuster 1722 .
The first width adjusting device 1721 is composed of a first support shaft 3081 , a third support shaft 3083 , a first support shaft fixing body 1741 and a second support shaft fixing transparent body 1762 .

The second width adjusting device 1722 is composed of a second support shaft 3082 , a second support shaft fixing body 1742 , and a first support shaft fixing transparent body 1761 .

The first support shaft 3081, the first support shaft 3081, and the third support shaft 3083 are configured by cylindrical bodies having the same diameter and length.
The first support shaft fixing body 1741, the second support shaft fixing body 1742, the first support shaft fixing transmission body 1761, and the second support shaft fixing transmission body 1762 are configured as oblong cubes of the same size.
The first support shaft fixed transparent body 1761 has a first through hole 1781 and a third through hole 1783 which have a circular cross section and are slightly larger in diameter than the diameters of the first support shaft 3081 and the third support shaft 3083, and are formed at predetermined intervals.
A second through hole 1782 having a circular cross section and a diameter slightly larger than the diameter of the second support shaft 3082 is formed in the second support shaft fixed transmitting body 1762 .

In the first width adjustment device 1721, the first support shaft 3081 and the third support shaft 3083 are arranged in parallel with a predetermined first spacing d1, the first support shaft fixing body 1741 is fixed at the left end, and the second support shaft fixing transmitting body 1762 is fixed at the right end. Therefore, the third width W3 between the first support shaft fixed body 1741 and the first support shaft fixed transparent body 1761 at the left end remains unchanged.

In the second width adjusting device 1722, the second support shaft fixed body 1742 is fixed to the right end of the second support shaft 3082, and the first support shaft fixed transparent body 1761 is fixed to the left end. Therefore, the fourth width W4 between the second support shaft fixed body 1742 and the first support shaft fixed transparent body 1761 at the right end portion does not change.

The intermediate portion of the first support shaft 3081 of the first width adjuster 1721 passes through the first through hole 1781 of the first support shaft fixed transparent body 1761, the intermediate portion of the third support shaft 3083 passes through the third through hole 1783 of the first support shaft fixed transparent body 1761, and the intermediate portion of the second support shaft 3082 of the second width adjuster 1722 passes through the second support shaft fixed transparent body 1762. It penetrates through the hole 1782 and is integrated.
As a result, the fifth width W5 between the first support shaft fixing body 1741 and the second support shaft fixing body 1742 is changed steplessly within the range where one end surface of the first support shaft fixed transmitting body 1761 contacts the first support shaft fixing body 1741 or the other end surface of the first support shaft fixing transmitting body 1761 contacts the second support shaft fixing transmitting body 1762.

In the 31st opening 3061o between the 31L bearing portion 3061L and the 31R bearing portion 3061R of the 31st shield 3061, the first support shaft fixed transmitting body 1761 is arranged.
In the 32nd opening 3062o between the 32L bearing portion 3062L and the 32R bearing portion 3062R of the 32nd shield 3062, a second support shaft fixed transmitting body 1762 is arranged.
In the 33rd opening 3063o between the 33rd L bearing portion 3063L and the 33rd R bearing portion 3063R of the 33rd shield 3063, the first support shaft fixed transmitting body 1761 is arranged.

The upper end of the 31st shield 3061 and the upper end of the 32nd shield 3062 are connected by the first interlocking cable 1821 .
The 32nd shield 3062 and the 33rd shield 3063 are connected by a second interlocking cable 1822 .
With this configuration, the right ends of the 31st shield 3061 and the 32nd shield 3062 and the left end of the 32nd shield 3062 overlap in the width direction at the open position OP.
The stopper device 108 locks the 32nd shield 3062 to hold it in the open position OP. Since the 31st shield 3061 is connected to the 32nd shield 3062 by the first interlocking cable 1821, the 31st shield 3061 is stationary at the open position OP. The 33rd shield 3063 is also rested in the open position OP.

When the 32nd shield 3062 is not locked by the stopper device 108, it moves to the shielding position CP by its own weight, so the 31st shield 3061 is pushed down by the 32nd shield 3062 and moves to the shielding position CP. The 33rd shield 3063 is pulled by the second interlocking cable 1822 and moves to the shield position CP.
The 31st shield 3061 and the 33rd shield 3063 overlap in the height direction at their shield positions CP.

In addition, since the first support shaft-fixed transmitting body 1761 is movable within the range of the 31st opening 3061o, and the second support shaft-fixing transmitting body 1762 is movable within the range of the 32nd opening 3062o, the overall width of the third shield 306 can be adjusted within this range.

Next, the third electric actuator 1143 in Embodiment 3 will be described with reference to FIG.
The third electric actuator 1143 in the third embodiment is a modification of the vibration actuator 152 in the second embodiment.
The second vibration actuator 1522 uses a so-called button-type vibration motor 184 and a vibration amplifier 186 .
As is well known, the button-type vibration motor 184 is a vibration motor that has a disc-shaped appearance and that generates vibration by rotating a rotor inside it around its axis. Button-type vibration motor 184 is arranged inside contact body 156 , and button-type vibration motor 184 and the inner surface of one side wall 156 W of contact body 156 are connected by connecting body 188 . The vibration of the button-type vibration motor 184 is transmitted to the contact body 156 via the connection body 188, and the contact body 156 can be vibrated efficiently.
A vibration amplifier 186 is a weight having a predetermined weight disposed within the contact body 156 and freely movable within the contact body 156 . In Embodiment 3, two metal nuts are used.
With this configuration, the vibration of the button-type vibration motor 184 vibrates the contact member 156 via the connection member 188 . Since the vibration amplifier 186 having a predetermined weight is also vibrated by the vibration of the contact member 156, the vibration width of the contact member 156 is amplified, and the contact member 156 can be vibrated efficiently. For the button-type vibration motor 184, for example, a disk-type vibration motor FM64G30T101 manufactured by Tokyo Parts Industry Co., Ltd. can be used.

Next, the action of Embodiment 3 will be described.
Awning device 100 for the organism growing area in Embodiment 3 is installed by placing first support shaft fixing body 1741 and second support shaft fixing body 1742 on first side wall 1161 and third side wall 1163 of water tank 116 .
The 32nd shield 3062 is moved to the open position OP to lean the 32nd shield 3062 against the stop end 126E. As a result, the 33rd shield 3063 is pushed by the 32nd shield 3062 and moved to the open position OP. The 33rd shield 3063 is pulled up via the second interlocking cable 1822 and moved to the open position OP. This places the third shield 306 in the open position OP and completes the preparation.
When a predetermined amount of sunlight enters the photovoltaic power generation device 112 , a predetermined output is obtained from the photovoltaic power generation device 112 , and the button-type vibration motor 184 operates to vibrate the contact member 156 via the connection member 188 . The vibration of the contact member 156 vibrates the weight, which is the vibration amplifier 186, and the vibration amplifier 186, which is a heavy weight, vibrates within the contact member 156, thereby amplifying the vibration of the contact member 156 and applying a predetermined force in the direction of arrow D to the solenoid actuator 136.
Therefore, as in the second embodiment, the stopper 126 is moved to the passing position PP, and the 32nd shield 3062 is moved to the shielding position CP by its own weight. By the movement of the 32nd shield 3062, the 31st shield 3061 is similarly moved to the shielding position CP, and the 33rd shield 3063 is pulled by the 32nd shield 3062 via the second interlocking cable 1822 and moved to the shielding position CP. Also, the 31st shield 3061 is pushed down by the 32nd shield 3062 .
As a result, the light receiving aperture 104 is covered with the third shield 306, the solar power generation device 112 is covered with the 32nd shield 3062, and power generation is stopped.

The awning device 100 for the organism-cultivating area of the present invention can shield the organism-cultivating area from sunlight by operating the electric actuator 114 using the photovoltaic power generation device 112 as a power source, so that the object of the invention can be achieved.

106 Shield
108 stopper device
112 Photovoltaic equipment
114 Electric Actuator
126 stopper
128 Stopper housing
136 Solenoid Actuator
154 Vibration Device
3061 31st Shield
3062 32nd Shield
3063 33rd Shield
CP shield position
OP open position
PP passing position
SP blocking position

A sixth invention according to claim 6 is configured as follows.
The electric actuator includes a vibrating device for applying vibration to the stopper and a solenoid actuator for applying a force to move the stopper from the blocking position to the passing position, and the vibrating device is arranged on the opposite side of the stopper with the shield interposed therebetween.

Claims (8)

a shielding body (106) movably provided from an open position (OP) erected to a shielding position (CP) for shielding the creature growing area from direct sunlight;
a blocking position (SP) in which the shield (106) is rested in the open position (OP) and a stopper device (108) movable to a passing position (PP) in which the shield (106) can move to the shield position (CP) by gravity;
a photovoltaic power generation device (112) placed at a position shielded from the direct sunlight by moving the shield (106) to the shielding position (CP);
An awning device for a living-growing area, comprising an electric actuator (114) for moving the stopper device (108) from the blocking position (SP) to the passing position (PP) by electric power from the solar power generation device (112). 2. The awning device for the biological growing area according to claim 1, wherein the stopper device (108) comprises a stopper housing (128) and a stopper (126) slidable relative to the stopper housing (128) and movable between the blocking position (SP) and the passing position (PP). 3. The awning device for a living-growing area according to claim 2, wherein said stopper (126) is inclined so as to be positioned downward as it moves away from said shield (106). 4. The awning device for a living-growing area according to claim 2 or 3, wherein the electric actuator (114) is a vibrating device (154) that vibrates the stopper (126). 5. The awning device for a living-growing area according to claim 4, wherein the electric actuator (114) is a solenoid actuator (136) that applies a force to the stopper (126) to move it from the blocking position (SP) to the passing position (PP). The electric actuator (114) includes a vibrator (154) that vibrates the stopper (126) and a solenoid actuator (136) that applies a force to move the stopper (126) from the blocking position (SP) to the passing position (PP),
6. The awning device for a living-growing area according to claim 4 or 5, wherein the vibration device (154) is arranged on the opposite side of the stopper (126) across the shield (106). The shield (106) is composed of a plurality of shields (3061, 3062, 3063),
The awning device for the living-growing area according to claim 1, characterized in that: The awning device for a living-growing area according to claim 1 or 7, wherein an aluminum sheet is arranged on the surface of the shield (106).

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