JP4677537B1 - Automatic sunshine system in a three-dimensional garden laid in a multi-story building - Google Patents

Abstract

An object of the present invention is to provide an automatic sunshine system for irradiating each floor garden with sunlight without being affected by the upper floor in the sunshine of a three-dimensional garden laid in a multi-layered building.
SOLUTION: In the sunlight of the garden 6 provided on each floor of the multi-layer building 1, the curved reflectors 113 and 3 and the solar power generator 12 are provided on the ceiling of each floor garden on the side receiving the sunlight on each floor of the garden 6 on each floor. A reflecting plate 113a or a curved reflecting plate 4 is provided, and an automatic angle adjusting device is attached to the reflecting plates 113 and 3 on the side receiving sunlight, and the automatic angle adjusting device is driven by solar power generation, and the reflecting plates 113 and 3 are connected to the ceiling. By irradiating the reflecting plates 113a and 4 with sunlight, the gardens 6 are irradiated with sunlight from the upper part broadly or concentratedly. Also, a condenser 7 and a projector 8 are provided on the ground or on the roof. The reflector 7 is connected to the reflector 9 in the projector, the projector 8 is connected to the reflector 4 on the ceiling of the garden 6 on each floor, and the reflector 4 You may irradiate the garden 6 on each floor with sunlight. You may use GPS for control of an automatic angle adjustment apparatus.
[Selection] Figure 1

Description

  The present invention relates to an automatic sunshine system in a three-dimensional garden laid in a multi-story building.

  There was a technology of a greening device that realized large-scale greening in an environment with a limited amount of sunlight. (See Patent Document 1)

JP-A-10-24839

  Cities are becoming increasingly taller and less green. In the high-rise buildings, green on the ground alone is not enough. Heat island pollution is also occurring. There is also the issue of carbon dioxide reduction. A three-dimensional garden (vertical garden) laid in the building is desired.

  In the case of a three-dimensional garden laid on a building, the sunshine that hits the gardens on each floor is affected by the upper floors, so the issue is how to shine the gardens on each floor.

In the sunshine in the garden on each floor of the multi-story building,
Provide a curved reflector on the ceiling of each floor garden,
A curved reflector and solar power generator on the side of the garden on each floor receiving sunlight.
Alternatively, a flat reflector and a solar power generation device linked to a collector are provided on the ground receiving sunlight of each floor garden, and the solar power generation device, the curved reflective plate on the side receiving sunlight or the flat reflective plate is automatically angled. Each floor garden is attached by attaching an adjusting device, and irradiating the curved curved reflector on the ceiling from the curved reflector or the flat reflector on the side receiving the sunshine by driving the automatic angle adjuster by photovoltaic power generation. It is an automatic sunshine system characterized by irradiating sunlight widely or concentrated from above.
The curved reflector and solar power generator on the side receiving sunlight are provided on the same rotation axis, and the curved reflector on the side receiving sunlight is such that the reflected light strikes the curved reflector on the ceiling. Install so that it is perpendicular to the light. The angle adjustment between the two will be described later.
At least the number of flat reflectors linked to the ground concentrator is provided for each floor garden. You may provide a condensing device and a plane reflector on a rooftop. In addition, an automatic angle adjustment device is also attached to the curved curved reflector on the ceiling, and the curved angle reflector on the side receiving sunlight or the automatic angle adjusting device for the flat reflector and the automatic angle adjusting device for the curved curved reflector on the ceiling are linked. good. Furthermore, you may attach an automatic moving apparatus according to an automatic angle adjustment apparatus.
By attaching the GPS to the condenser, the position of the planar reflector can be calculated, and the angle of the planar reflector can be calculated by the automatic angle adjustment device to drive the planar reflector.

  The energy for automatically irrigating the gardens on each floor and the energy for automatically supplying nutrient solutions and chemicals to the gardens on each floor may be generated by the solar power generation.

  Sunlight on urban buildings and laying a sustainable three-dimensional garden (vertical garden) will improve the cityscape and contribute to reducing heat islands and carbon dioxide. It also moisturizes the people who live and work there. Instead of a garden, it can be a vegetable garden or a rice field.

  See (1) in FIG. A curved reflector (4) and a solar power generation device (13) are provided on the side of each floor garden (6) receiving sunlight, and an automatic angle adjusting device (not shown) is attached to the curved reflector (4). Yes. The automatic angle adjusting device for the curved reflector (4) is driven by a solar power generation device (13) to irradiate the gardens (6) on each floor from the curved reflector (4) or curved on the ceiling of each garden. A reflecting plate (4 ′) is provided, and the curved-surface reflecting plate (4 ′) on the ceiling is irradiated with the sunlight from the curved reflecting plate (4) that receives the sunshine, so that each floor garden (6) is widely irradiated with sunlight from above. To do. The automatic angle adjusting device is not shown. Similarly to the curved reflector (4) that receives sunlight, it is desirable that the solar generator be tracked by the sun. Therefore, the photovoltaic generator is arranged side by side with the curved reflector (4). The curved reflection plate (4) can be a two-dimensional curved reflection plate (kamaboko shape) or a three-dimensional curved reflection plate (surface shape of a convex lens). When the kamaboko-shaped curved reflector is used for uniaxial rotation, the rotation axis is the east-west axis. From the morning to the evening, the sunlight reflected from the curved reflector (4) hits the ceiling moves greatly from east to west (the north-south movement can be adjusted by rotation). Therefore, the curved curved reflector (4 ') receiving the sunlight is required to have a length and a shape. Since the curved reflector (4) that receives sunlight is the same cubic surface as the surface of the convex lens and is biaxially rotated, it is possible to irradiate the curved reflector (4 ′) of the ceiling with all of the sunlight received roughly. It is easy and accurate to control the irradiation range and amount of sunlight on each floor garden. Whether to use a second-order curved reflector having a length and an area or one or a plurality of third-order curved reflectors is determined by the irradiation range, amount of irradiation, and cost of sunlight on each floor garden.

  See the upper part of (2) in FIG. Making the curved curved reflector (4 ') smaller by making the curved curved reflector (4) that receives sunlight into a concave reflector, collecting sunlight and irradiating the curved curved reflector (4') on the ceiling Can do.

  See (2) in FIG. On the ground receiving sunlight of each floor garden (6), a condenser (7), at least one flat reflector (9) and a solar power generation device (13) are installed on each floor garden, and the ceiling of each floor garden (6). Is provided with a curved reflector (4 ′). An automatic angle adjustment device is attached to the light collector (7) or the flat reflector (9), the light collector (7) and the flat reflector (9) are interlocked, and the automatic angle adjuster is driven by photovoltaic power generation. Then, sunlight is irradiated from the condenser (7) to the flat reflector (9) and from the flat reflector (9) to the curved reflector (4 ′) of the ceiling of each floor garden (6), and the curved reflection of the ceiling is performed. It is an automatic sunshine system characterized by spreading sunlight from the top to the garden (6) on each floor from the board (4 '). The number of planar reflectors (9) is at least as many as the number of gardens on each floor. The automatic angle adjustment device is omitted.

In the sunshine system of the garden (6) on each floor of the multi-story building (1),
Concentrator (7), solar power generator (13),
A first flat reflector (9) is provided at the rear of the condenser (7),
Provide at least one second flat reflector (9 ′) for each floor that irradiates the curved reflector (4) provided on the side receiving sunlight in the garden on each floor;
A curved reflector (4 ') is installed on the ceiling of each floor garden.
An automatic angle adjustment device is attached to the condenser (7), the first flat reflector (9), and the second flat reflector (9 ′),
The collector (7), the first planar reflector (9), and the second planar reflector (9 ′) are interlocked,
The automatic angle adjustment device is driven by the solar power generation device (13),
From the condenser (7) to the first planar reflector (9),
From the first flat reflector (9) to the second flat reflector (9 ′),
From the second flat reflector (9 ') to the curved reflector (4) on the side receiving the sunlight of each floor garden,
Irradiate the curved reflector (4 ') on the ceiling from the curved reflector (4) on the side receiving sunlight in the garden on each floor,
From the ceiling curved reflector (4 ') to each floor garden,
It is characterized by irradiating with wide or concentrated sunlight from the top.
In FIG. 2, each floor garden (6) faces the south side. Each floor garden (6) can be provided facing north. When it is provided facing the north side, it is only necessary to irradiate the curved reflecting plate (4) that receives sunlight from each floor directly from the first flat reflecting plate (9).

Refer to (1) in FIG. In the sunshine system of the garden (6) provided on each floor of the multi-layer building (1), the condenser (7) and at least one flat reflector (9) are integrated,
The sunlight collected by the condenser (7) is reflected by at least one flat reflector (9).
By irradiating each floor garden (6) with sunlight directly or on the curved reflector (4 ') on the ceiling,
Each floor garden (6) is irradiated with sunlight.
The curved reflector (31) of the condenser is hinged (102) to the support (101),
Since the column (101) also rotates automatically, the condenser (7) can track the sun. The height of the condenser (7) can be adjusted by moving the column (101) up and down with a jacky (103) or the like.
FIG. 3B is a cross-sectional view taken along the line AA in FIG.
The back side of the flat reflector (9) is a partial spherical body (99),
The automatic angle adjusting device is provided with a partial spherical concave surface (91) having the same radius as the partial spherical body (99),
A linear motor is installed in the automatic angle adjustment device or the partial spherical body (99),
By automatically driving the linear motor,
The sunlight from the condenser (7) is sent from the flat reflector (9) to the gardens (6) on each floor.
It is characterized by irradiating sunlight directly or on the curved reflector (4 ′) on the ceiling.
By providing three or more magnetic poles (92) on the partial spherical concave surface (91) and the partial spherical surface of the partial spherical body (99), the partial spherical body (99) can be freely moved by a linear motor.
FIG. 4 shows the use of the condenser (7) and the flat reflector (9) to irradiate the curved curved reflector (4 ′) on the ceiling of each floor garden (2) with sunlight, and to create a curved curved reflector (4) on the ceiling. This is an example in which the garden (2) on each floor is irradiated with a wide range of sunlight from the top.

See (2) in FIG. The condenser (7) and the flat reflector (9) are integrated,
Attach GPS (27) to the central reflector (32) of the collector,
The automatic angle adjustment device for the flat reflector (9) automatically calculates the position of the flat reflector (9) from the position of the central reflector (32) of the condenser (7) by the GPS (27),
Further, a plane for irradiating the curved curved reflector (4) with sunlight from the positions of the central reflector (32) and the planar reflector (9) and the curved curved reflector (4) of the condenser. The angle of the reflector (9) is automatically calculated, the planar reflector (9) is driven using the solar power generation device (13),
The flat reflector (9) irradiates the curved reflector (4) on the ceiling of each floor garden with sunlight.

See FIG. The condenser (7) and the first flat reflector (9) are integrated,
A GPS (27) is attached to the central reflector (32) of the condenser that directly irradiates the first planar reflector (9) with sunlight,
Fixing the center position of the second flat reflector (9 ′),
The curved reflector (4) on the side receiving sunlight in the garden on each floor is set to an angle that reflects the sunlight irradiated from the second planar reflector (9 ′) to the curved reflector (4 ′) on the ceiling,
The automatic angle adjusting device for the first flat reflector (9) is:
The position of the first flat reflector (9) is automatically calculated from the position of the central reflector (32) of the condenser by GPS,
Furthermore, from the position of the central reflector (32) of the condenser, the position of the first planar reflector (9), and the center position of the second planar reflector (9 ′), the second planar reflector ( 9 ′) automatically calculates the angle of the first planar reflector (9) for irradiating sunlight ,
The first planar reflector (9) is driven using the solar power generation device (13),
The automatic angle adjusting device for the second planar reflector (9 ′) is:
From the position of the first plane reflector (9), the center position of the second plane reflector (9 '), and the center position of the curved reflector (4) on the side receiving the sunlight of each floor garden, sunshine on each floor garden Automatically calculating the angle of the second planar reflector (9 ′) to irradiate sunlight on the curved reflector (4) on the receiving side ;
The second planar reflector (9 ′) is driven using the solar power generation device (13),
Sunlight is applied to the curved reflector (4) on the ceiling of each garden from the curved reflector (4) on the side receiving sunlight in each garden.

  The automatic angle adjustment device automatically detects the position of the sun based on the position and date of the condenser (7) by the GPS (27) and causes the condenser (7) to track the sun. To do.

FIG. 5 shows the movement of the sun (S), the angle of the solar power generation devices (13A to 13D) that track the sun, and the angle of the curved reflectors (4A to 4D) that irradiate sunlight onto the curved reflector (4 ′) on the ceiling. It is sectional drawing and a top view which showed the relationship. First, see as a cross-sectional view.
A horizontal line on the drawing indicates a horizontal line (H), and a vertical line (V) indicates a vertical line. The positions of solar power generation for tracking the sun when the sun (S) is at altitudes A, B, C, and D are 13A, 13B, 13C, and 13D, respectively, and the curved reflectors (4A to 4D) are provided. The angles at which the curved curved reflector (4 ′) on the ceiling is irradiated are 4A, 4B, 4C, and 4D, respectively. FIG. 4 is a cross-sectional view showing that the curved reflection plate (4) has a movement angle for irradiating the curved reflection plate (4 ′) on the ceiling with sunlight is ½ of the movement angle of the solar power generation apparatus that tracks the sun. 5 indicates.
Next, see as a plan view. The vertical line on the drawing indicates the north-south axis (So-N), and the horizontal line (EW) indicates the east-west axis. The positions of solar power generation for tracking the sun when the sun (S) is at the azimuth angles A, B, C, and D are 13A, 13B, 13C, and 13D, respectively, and curved reflectors (4A to 4D) However, the angles at which the curved curved reflector (4 ′) on the ceiling is irradiated are 4A, 4B, 4C, and 4D, respectively. The figure shows that the moving angle for the curved reflecting plate (4) to irradiate the curved reflecting plate (4 ') on the ceiling in plan view is ½ of the moving angle of the solar power generator that tracks the sun. 5 indicates. Therefore, the movement angle for the curved reflecting plate (4) to irradiate the curved reflecting plate (4 ′) on the ceiling with sunlight is ½ of the moving angle of the solar power generator that tracks the sun.
If the solar power generation devices (13A to 13D) and the curved reflectors (4A to 4D) move together, the position of the curved reflector (4D) comes to the position 4D ′ in FIG. The sunlight of (S) goes in the direction of D ′ and greatly deviates from the curved curved reflector (4 ′) on the ceiling.

The solar power generation device (13) is attached to the outer periphery or the center of the condenser (7) so that the power generation amount of the solar power generation device (13) or the solar power generation device (13) on each floor is maximized. When the automatic angle adjusting device is controlled, the automatic angle adjusting device causes the condenser (7) or the solar power generation device (13) of each floor garden to track the sun. Further details will be described below.
The azimuth angle At and altitude Ht of the sun at time t at a point are given by:
At = Ato ± a 0 ≦ a ≦ am
Ht = Hto ± h 0 ≦ h ≦ hm
At; Azimuth angle at t Ht; Altitude at time t Ato; Standard azimuth angle at t Hto; Standard altitude at t time a; Azimuth deviation angle h; Altitude deviation degree am; Maximum azimuth deviation angle hm; Therefore, the following control can be performed.
Control of the azimuth angle: Change the angle of the automatic angle adjustment device of the hourly photovoltaic power generation device (13) within the range of Ato ± am, and the angle or deviation angle when the amount of photovoltaic power generation becomes maximum within that angle range Detect.
↓
The automatic angle adjustment device is driven according to the angle or the deviation angle at which the photovoltaic power generation is maximized.
↓
Control of solar altitude ↓
Same as azimuth control.
The numerical values for Ato and Hto may be those for spring equinox or autumn equinox when control is left to the automatic angle adjustment device throughout the year. At that time, the values of am and hm are calculated from the azimuth and altitude of the winter or summer solstice. By setting the numerical values of Ato and Hto every four seasons or every month, the movement angle of the automatic angle adjusting device can be reduced.

A vertical light detection device (200) is attached to the concentrator (7) or the solar power generation device (13) on each floor, and an automatic angle adjustment device is used so that the power generation amount of the solar power generation device (13) is maximized. Instead of being controlled, the vertical light detection device (200) controls the automatic angle adjustment device so that the condenser (7) or the solar power generation device (13) on each floor is perpendicular to sunlight. Thus, the automatic angle adjusting device may cause the condenser (7) or the solar power generation device (13) of each floor garden to track the sun.
FIG. 6 shows an embodiment of the vertical light detection device (200). FIGS. (1), (2), (3), and (4) are respectively a cross-sectional view taken along line AA in FIG. (2), a front view, and a cross-sectional view taken along line BB in FIG. Show. Since the hole (202) is formed in the surface (201) that receives sunlight, and the optical sensor (203) is attached directly below the hole (202), the optical sensor (203) Only sunlight that irradiates perpendicularly to) can be detected. Therefore, the automatic angle adjustment device is driven by the light sensor (203) of the vertical light detection device (200) so as to detect sunlight, thereby allowing the light collector (7) or the solar power generation device (13) on each floor to be detected. The sun can be tracked.

  See (1) and (2) in FIG. The angle of the curved reflecting plate (4 ′) on the ceiling or the curved reflecting plate (4) on the side receiving sunlight of each floor garden is an angle at which the sunlight irradiates the central portion of the range where the sunlight of each floor garden is required at noon. To do. Thereby, even if the central part of the range irradiated by the curved curved reflector (4 ′) on the ceiling moves with the movement of the sun, the largest amount of sunlight is applied to the range where sunlight is required in the gardens on each floor (6). Can be irradiated. An automatic angle adjusting device is also attached to the ceiling curved reflector (4 '), and the automatic angle adjusting device for the curved reflector (4) or flat reflector (9) on the side receiving sunlight, and the curved curved reflector (4) In conjunction with the automatic angle adjustment device of '), the range irradiated by the curved curved reflector (4') on the ceiling can be narrowed down.

See FIG. 1 and FIG. Sunlight may be directly applied to each floor garden (6) from the curved reflecting plate (4) and the flat reflecting plate (9) on the side receiving the sunlight. For planting, sunshine from the top, which is close to the natural state, is desirable. However, in each floor garden (6) with a ceiling, it cannot be denied that sunshine is disadvantageous compared to the ground or rooftop garden. Therefore, it is better to receive not only the sunshine from the top but also the sunshine from the front or the bottom at the same time. If you have a vine plant on the ceiling, sunshine from below is effective. When the condenser (7) is above the gardens on each floor, it is effective to directly irradiate the gardens on each floor from the flat reflector (9).
You may provide an automatic moving apparatus in the curved reflector (4) which receives the said sunlight, the flat reflector (9), or the curved reflector (4 ') of a ceiling. In paragraph [0009], “Sunlight reflecting on the curved reflector (4) on the side receiving sunlight from the morning to the evening hits the ceiling, the curved reflector (4) on the side receiving sunlight is uniaxially rotated about the east-west axis. In this case, it moves greatly from east to west (the north-south movement can be adjusted by rotation). Therefore, the curved reflector on the ceiling that receives sunlight is required to have a length and a shape. " However, by providing an automatic moving device that moves from east to west on the curved reflector (4) on the side receiving sunlight or the curved reflector (4 ') on the ceiling, the length of the reflector is shortened, and the sunlight received by the garden is reduced. The effective rate can also be increased.

See (1) and (2) in FIG. A temperature sensor (117) is provided in the room facing each garden (6), the temperature sensor (117) detects the room temperature, and the curved reflector (4) on the side receiving sunlight of each floor garden (6) By controlling the driving of the automatic angle adjusting device for the reflector (9) or the curved curved reflector (4 ′) on the ceiling, the room temperature can be adjusted by adjusting the intake of radiant heat into the room. On the other hand, in order to lower the indoor temperature, as shown in a separately applied irrigation system, the water of planting of each floor garden (6), the heat of vaporization due to the evaporation of water of the water-retaining pavement floor or water of the pond is used. For example,
1 Detect the lower limit of the predetermined temperature range with the room temperature sensor →
2 Drive the curved reflector on the ceiling to irradiate sunlight indoors → Increase in temperature →
3Detect the upper limit of the predetermined temperature range of the room temperature with the room temperature sensor →
4 Drive the curved reflector on the ceiling to block the sunlight to the indoor side.
It is. For example,
1Detect the upper limit of the predetermined temperature range of the room temperature with the room temperature sensor →
2 Drive the curved reflector on the ceiling to block sunlight to the indoor side → Temperature drop 3 Further, drive the reflector that receives sunlight to block sunlight from entering the garden → Temperature drop →
4 If the lower limit of the predetermined temperature range is still not reached, irrigation, watering or spraying the garden to lower the temperature in the garden by heat of vaporization →
5 Take in the cool air in the garden by ventilation or radiant heat.
It is. The above driving is automatically performed by turning on / off the power of the driving device (automatic angle adjusting device, automatic moving device, automatic opening device) in response to a signal from the indoor sensor.

FIG. 1A is a cross-sectional view of an embodiment of an automatic sunshine system, and FIG. 2B is a cross-sectional view of another embodiment of an automatic sunshine system. It is sectional drawing of another automatic sunshine system Example. FIG. 1A is a cross-sectional view of a condenser and a flat reflector, and FIG. 2B is a cross-sectional view taken along line AA of FIG. Using the condenser (7) and the flat reflector (9), the curved reflector (4 ') on the ceiling of each floor garden (2) is irradiated with sunlight, and the garden on each floor from the curved reflector (4') on the ceiling. (2) It is a perspective view of the Example which expanded and spread sunlight from the upper part to (2). It is sectional drawing and a top view which showed the relationship of the angle of a movement of the sun (S), a solar power generation device (13A-13D), and a curved-surface reflecting plate (4-4D). 1A is a cross-sectional view taken along the line AA in FIG. 2B, FIG. 2B is a front view, FIG. 3C is a cross-sectional view taken along the line BB in FIG. 1A, and FIG. is there.

DESCRIPTION OF SYMBOLS 1 Multi-story building 2 Three-dimensional garden 4 Curved reflector on the side receiving sunlight 4 'Curved reflector on the ceiling 6 Garden on each floor 7 Condenser 9 Planar reflector 9' Second planar reflector 13 Solar power generator 14 Rotation Axis 27 GPS
31 (within the condenser) Curved reflector 32 (within the condenser) Central reflector 91 Partial spherical concave surface 92 Magnetic pole 99 Partial spherical body 117 Temperature sensor 200 Vertical light detector 201 Surface receiving sunlight 202 Hole 203 Optical sensor

Claims (14)

In the sunshine system of the garden (6) on each floor of the multi-story building (1),
A collector (7), a solar power generation device (13) on the ground receiving sunlight of each floor garden, and
Provide at least one flat reflector (9) for each floor that irradiates the ceiling of each floor garden,
A curved reflector (4 ') is installed on the ceiling of each floor garden.
Attach an automatic angle adjustment device to the condenser (7) and the flat reflector (9),
The automatic angle adjustment device of the condenser (7) and the flat reflector (9) is linked,
The automatic angle adjustment device is driven by a solar power generation device (13),
From the condenser (7) to the flat reflector (9),
Irradiate the curved reflector (4 ′) of the ceiling from the plane reflector (9) with sunlight,
From the curved reflector (4 ') on the ceiling to the garden (6) on each floor,
An automatic sunshine system characterized by irradiating with wide or concentrated sunlight from the top. In the sunshine system of the garden (6) on each floor of the multi-story building (1),
Concentrator (7), solar power generator (13),
A first flat reflector (9) is provided at the rear of the condenser (7),
Provide at least one second flat reflector (9 ′) for each floor that irradiates the curved reflector (4) provided on the side receiving sunlight in the garden on each floor;
A curved reflector (4 ') is installed on the ceiling of each floor garden.
An automatic angle adjustment device is attached to the condenser (7), the first flat reflector (9), and the second flat reflector (9 ′),
The collector (7), the first planar reflector (9), and the second planar reflector (9 ′) are interlocked,
The automatic angle adjustment device is driven by the solar power generation device (13),
From the condenser (7) to the first planar reflector (9),
From the first flat reflector (9) to the second flat reflector (9 ′),
From the second flat reflector (9) to the curved reflector (4) on the side receiving the sunlight of each floor garden,
Irradiate the curved reflector (4 ') on the ceiling from the curved reflector (4) on the side receiving sunlight in the garden on each floor,
From the ceiling curved reflector (4 ') to each floor garden,
An automatic sunshine system characterized by irradiating with wide or concentrated sunlight from the top. In the sunshine system of the garden (6) on each floor of the multi-story building (1),
Integrating the condenser (7) and at least one planar reflector (9);
The sunlight collected by the condenser (7) is reflected by a plurality of planar reflectors (9).
By irradiating each floor garden (6) with sunlight directly or on the curved reflector (4 ') on the ceiling,
3. The automatic sunshine system according to claim 1 or 2, characterized in that each floor garden (6) is irradiated with sunlight. The back side of the flat reflector (9) is a partial spherical body (99),
The automatic angle adjusting device is provided with a partial spherical concave surface (91) having the same radius as the partial spherical body (99),
A linear motor is installed in the automatic angle adjustment device or the partial spherical body (99),
By automatically driving the linear motor,
The sunlight from the condenser (7) is sent from the flat reflector (9) to the gardens (6) on each floor.
4. The automatic sunshine system according to claim 3, wherein sunlight is irradiated directly or on the curved reflector (4 ') on the ceiling. The condenser (7) and the flat reflector (9) are integrated,
Attach GPS (27) to the central reflector (32) of the collector,
The automatic angle adjustment device for the flat reflector (9) automatically calculates the position of the flat reflector (9) from the position of the central reflector (32) of the condenser (7) by the GPS (27),
Further, a plane for irradiating the curved curved reflector (4) with sunlight from the positions of the central reflector (32) and the planar reflector (9) and the curved curved reflector (4) of the condenser. The angle of the reflector (9) is automatically calculated, the planar reflector (9) is driven using the solar power generation device (13),
The automatic sunlight system according to claim 1, wherein the flat reflector (9) irradiates the curved reflector (4) on the ceiling of each floor garden with sunlight. The condenser (7) and the first flat reflector (9) are integrated,
A GPS (27) is attached to the central reflector (32) of the condenser that directly irradiates the first planar reflector (9) with sunlight,
Fixing the center position of the second flat reflector (9 ′),
The curved reflector (4) on the side receiving sunlight in the garden on each floor is set to an angle that reflects the sunlight irradiated from the second planar reflector (9 ′) to the curved reflector (4 ′) on the ceiling,
The automatic angle adjusting device for the first flat reflector (9) is:
The position of the first flat reflector (9) is automatically calculated from the position of the central reflector (32) of the condenser by GPS,
Furthermore, from the position of the central reflector (32) of the condenser, the position of the first planar reflector (9), and the center position of the second planar reflector (9 ′), the second planar reflector ( 9 ′) automatically calculates the angle of the first planar reflector (9) for irradiating sunlight,
The first planar reflector (9) is driven using the solar power generation device (13),
The automatic angle adjusting device for the second planar reflector (9 ′) is:
From the position of the first plane reflector (9), the center position of the second plane reflector (9 '), and the center position of the curved reflector (4) on the side receiving the sunlight of each floor garden, sunshine on each floor garden Automatically calculating the angle of the second planar reflector (9 ′) to irradiate sunlight on the curved reflector (4) on the receiving side;
The second planar reflector (9 ′) is driven using the solar power generation device (13),
3. The automatic sunshine system according to claim 2, wherein sunlight is irradiated to the curved reflector (4) on the ceiling of each floor garden from the curved reflector (4) on the side receiving sunlight of each garden.   The automatic angle adjusting device automatically detects the position of the sun based on the position and date of the condenser (7) by the GPS (27) and causes the condenser (7) to track the sun. The automatic sunshine system according to claim 5 or 6. A curved reflector (4) and a solar power generation device (13) are provided on the side of the garden (6) receiving sunlight, and a curved reflector (4 ′) is provided on the ceiling of each garden.
Attach an automatic angle adjustment device to the curved reflector (4) or solar power generation device (13) on the side receiving sunlight in each garden (6),
From the curved reflector (4) on the side where the automatic angle adjustment device is driven by the solar power generation device (13) and receives sunlight of the gardens (6) on each floor,
The automatic sunshine system according to claim 1 or 2, wherein the curved reflector (4 ') on the ceiling is irradiated with sunlight. The curved reflector (4) on the side receiving sunlight in the gardens (6) on each floor is linked to the automatic angle adjustment device of the solar power generation device (13).
By making the movement angle of the curved reflector (4) on the side receiving sunlight in the gardens (6) on each floor half of the movement angle of the photovoltaic power generation device (13),
The curved reflectors (4) on the side of the gardens (6) on each floor receiving sunlight receive sunlight,
9. The automatic sunshine system according to claim 8, wherein the curved reflective plate (4 ') on the ceiling can be irradiated with sunlight from the curved reflective plate (4) on the side receiving sunlight of each floor garden (6).   The automatic angle adjustment device is controlled so that the amount of power generated by the solar power generation device (13) is maximized, so that the automatic angle adjustment device is connected to the condenser (7) or the solar power generation device (13). The automatic sunshine system according to any one of claims 1 to 6, wherein the sunshine is tracked. An automatic angle adjustment device is also attached to the curved reflector (4 ′) on the ceiling,
An automatic angle adjustment device for the curved reflector (4) or the planar reflector (9) on the side receiving sunlight of the gardens (6) on each floor;
In conjunction with the automatic angle adjustment device of the curved reflector (4 ') on the ceiling,
The solar power generator (13) drives an automatic angle adjustment device for the curved reflector (4), the flat reflector (9) or the curved reflector (4 ') on the side receiving sunlight of the gardens (6) on each floor. The automatic sunshine system according to any one of claims 1 to 10, wherein:   9. The sunlight according to claim 1, 2, or 8, wherein sunlight is directly applied to each floor garden (6) from the curved reflector (4) or the flat reflector (9) on the side receiving sunlight of each floor garden (6). Automatic sunshine system.   The automatic moving device is provided on the curved reflector (4), the flat reflector (9) or the curved reflector (4 ') on the side receiving sunlight of each floor garden (6). The automatic sunshine system as described in any one of 5 or 7-11. A temperature sensor (17) is provided in the room facing the garden (6) on each floor,
The room temperature is detected by the temperature sensor (17),
By controlling the driving of the automatic angle adjustment device of the curved reflector (4), the flat reflector (9) or the curved reflector (4 ') on the side receiving sunlight of each floor garden (6), The automatic sunshine system according to any one of claims 1 to 13, wherein the room temperature is adjusted by adjusting the intake of radiant heat.

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