JPH0226103Y2 - - Google Patents

Description

[Detailed Description of the Invention] [Industrial Field of Application] The present invention relates to a shade elimination device that irradiates reflected sunlight onto a shaded area of a building or the like.

[Conventional technology]

In recent years, as entrances to cities have become more concentrated, buildings have become increasingly taller and larger. Naturally, the number of hours of sunlight in the valleys between buildings and in the shade of large buildings has been extremely reduced throughout the year, causing severe damage. There are areas in the shade where there is no sunlight at all, causing semi-permanent damage to nearby residents with little hope of improvement due to various types of pollution. One possible solution to this type of pollution is the use of electric artificial lighting.

[The problem that the idea attempts to solve]

However, although this artificial lighting, which can be called an artificial sun, can restore the brightness of the shaded areas, it is clear that it cannot restore all the solar energy that the sun provides to the earth. Not only is it completely impossible to fundamentally solve pollution related to sunlight with lighting, but the work efficiency of using electrical energy is extremely low, and electrical energy is wasted. This is undesirable because it goes against the era of resource conservation through artificial lighting.

The purpose of the present invention is to provide a device that utilizes inexhaustible solar energy.

[Means to solve the problem]

In order to achieve the above object, the shade eliminating device according to the present invention includes a plurality of reflectors each having a mirror surface that illuminates the shaded area with reflected sunlight, a support mechanism for the reflectors, and a drive device for each reflector. and a posture control mechanism for controlling the posture of the reflector, wherein the reflectors are arranged in parallel in a plurality of upper and lower stages at predetermined intervals and are each attached to a support mechanism, The support mechanism supports the reflector at each stage so as to be angularly displaced around the horizontal axis (x-axis) and the vertical axis (y-axis), and the drive device moves the reflector at each stage around the x-axis. The attitude control mechanism consists of a motor that rotates forward and backward rotations around the y-axis, and a motor that rotates the support mechanism that supports each stage of reflectors forward and backward around the y-axis. It issues a sun tracking command based on position data, rotates each motor of the drive device around the x-axis and y-axis, and transmits the sun's rays that are incident on the reflectors at each stage to reflect them in the shaded areas. This is to control the attitude of the reflector depending on the angle.

[Principle/effect]

By reflecting the sunlight on the mirror surface of the reflector, the reflected light of the sunlight can be applied to the shaded area.
By the way, the sun's rays are parallel rays, and the position of the sun changes from moment to moment throughout the year or even within the sunshine hours of the day as the earth rotates. When irradiating light, the angle of incidence and reflection angle of the sun's rays on the reflector changes from time to time, and the irradiation position of the reflected light of the sun's rays on the shaded area changes, causing the reflected light of the sun's rays to change from time to time. Even if you try to irradiate the shaded areas, it is impossible to completely eliminate the shaded areas. Therefore, it is necessary to control the attitude of the reflector according to the position of the sun to adjust the angle of incidence and reflection angle of the sunlight on the mirror surface of the reflector.

Therefore, as shown in FIG. 1, the reflector 1 is supported by a support mechanism, for example, a support 2 that is rotatably supported around the horizontal axis Installed on the roof of the building.
In FIG. 1A, an arc-shaped arm 5 is supported on a base 4 so as to be angularly displaced around the vertical axis y, and a drive device such as a motor 6 is used to angularly displace the arm 5 around the vertical axis y.
is installed on the arm 5, and the reflector 1 is pivotally supported on the arm 5 so as to be angularly displaced around the horizontal axis x, and a horizontal drive device, such as a motor, is installed on the arm 5 to angularly displace the reflector 1 around the horizontal axis x. 7 was installed, and the motor 6 was rotated in the forward and reverse directions to angularly displace the reflector 1 around the vertical axis y, and the motor 7 was rotated in the forward and reverse directions to angularly displace the reflector 1 around the horizontal axis x. This is an example. In addition, in FIG. 1B, a frame 9 is pivoted on an arm 8 fixed to the base 4 so as to be angularly displaced around the horizontal axis x, and the reflector 1 is angularly displaced on the frame 9 around the vertical axis y. The motor 6 is used to move the reflector 1 as shown in Fig. 1A.
The reflector 1 is angularly displaced with respect to the frame 9 around the vertical axis y, and the frame 9 is angularly displaced by the motor 7.
This is an example of angular displacement around the horizontal axis x.

Incidentally, the motors 6 and 7 used as the driving device may be a pulse motor, a stepping motor, or the like.

The reflector 1 may be a glass mirror made of transparent glass lined with a mercury film or the like, or a metal mirror made of a metal plate with a mirror finish, and is particularly required to be resistant to corrosion and to have good reflection efficiency on the mirror surface 1a of the reflector 1. be done. Further, the mirror surface 1a of the reflector 1 needs to be regularly cleaned by cleaning means such as water jetting to maintain good reflection efficiency. Further, as the reflector 1, a plane mirror or a concave mirror is appropriately used depending on the place of use. Alternatively, as shown in FIG. 1B, the reflector 1 is
After the sunlight is reflected on the mirror surface 1a of the reflector 1, the reflected light of the sunlight on the mirror surface 1a of the reflector 1 may be irradiated onto the shaded area.

Figures 1A and 1B show an example in which two reflectors are installed side by side in the horizontal direction, but when installing two or more reflectors, it is advantageous to use the space above from the standpoint of utilizing the installation space. It is. If two or more reflectors are installed using the upper space, the amount of reflected light can be increased and a narrow space can be effectively used for installation.

〔Example〕

Embodiments of the present invention will be described below using figures.

Figures 2A and 2B show the basic configuration of the proposed device. That is, as shown in FIG. 2 A and B, the present invention includes a plurality of reflectors 1, 1, 1, .
, a support 2 for the reflector 1 , a drive device for each reflector 1 , and an attitude control mechanism for controlling the attitude of the reflector 1 .

In FIG. 2B, the reflectors 1 are arranged in parallel in a plurality of upper and lower stages at predetermined intervals and are attached to the support body 2, respectively. The support body 2 has a frame shape, and supports the reflectors 1, 1... of each stage installed vertically within the frame so as to be angularly displaced about the horizontal axis (x axis) and the vertical axis (y axis). Support 2
is supported on a base 4 so as to be angularly displaced around the vertical axis y, and a motor 6 is installed for angularly displacing the support 2 around the vertical axis y. On the other hand, support 2
A motor 7 is installed at each stage to angularly displace each reflector 1 around the horizontal axis x.
Here, a motor 7 that rotates the reflector 1 of each stage forward and backward around the x-axis, and a motor 6 that rotates the support body 2 that supports the reflector 1 of each stage forward and reverse around the y-axis, are used. It constitutes a driving device. A motor 7 for angularly displacing the reflector 1 around the horizontal axis x
is provided for each stage of reflectors, and there is one motor 6 for angularly displacing the support 2 around the vertical axis y.

Next, the attitude control mechanism 1 drives the support mechanism according to changes in the position of the sun and adjusts the reflector 1 to the attitude necessary to irradiate the shaded area with reflected sunlight.
1 will be explained. In FIG. 3, the attitude of the reflector 1 is controlled by driving one motor 6 and the motor 7 for each reflector in response to instructions from a program stored in a storage device such as a computer.
The number of hours of sunlight throughout the year at the point of use, the position and trajectory of the sun during that number of hours of sunshine, and the angle of incidence of sunlight on the mirror surface of the reflector to concentrate the reflected light of the sun's rays on the shaded area at that position of the sun. ,
Necessary data such as the angle of reflection, the angle of elevation of the sun's rays that changes with each season, and the attitude of the reflector with respect to the angle of elevation are input into a storage device 12 such as a computer by a program. Then, data is reproduced from the storage device 12 from sunrise to sunset and amplified by the amplifier 13, and the motors 6 and 7 are driven by the output. By driving the motors 6 and 7, the attitude of the reflector 1 is controlled according to the position of the sun, which changes from time to time, and the mirror surface 1a of the reflector 1 is
The incident angle and reflection angle of the sunlight S relative to the sun are adjusted, and the reflected light S' of the sunlight is concentrated on the shaded area d.

Further, data regarding the elevation angle of the sun's rays is reproduced from the storage device 12, and the motors 6 and 7 are driven by the output, and the data is responsive to the shift in the sun's position due to the elevation angle changing as the trajectory of the sun's rays changes. The incident angle and reflection angle of the sunlight with respect to the mirror surface 1a of the reflector 1 are adjusted, and the reflected light S' of the sunlight is concentrated on the shaded area d according to the change in the elevation angle of the sunlight. . Since the attitude control mechanism 11 shown in FIG. 3 searches for the sun's position in response to commands from a stored program, it can accurately determine the sun's position even when the sun's rays are weak, such as during cloudy or rainy days. Trackable, reflector 1 for each stage
Not only can the reflected light of the sun's rays received by the sun be irradiated onto the shaded areas, but also the reflected light of the sun's rays can be irradiated onto the shaded areas in the same way even if the elevation angle of the sun changes.

The attitude control mechanism 11 shown in FIGS. 4A and 4B performs control based on a potential difference caused by a difference in the amount of incident sunlight. That is, at least three or more photoelectric elements (four in the example) are incorporated into the cylinder 14 with an open front surface to provide directivity.
15 ₁ , 15 ₂ , 15 ₃ , and 15 ₄ are arranged in a triangular or polygonal shape (quadrangular in the embodiment) with each pointing in a different direction to detect the position of the sun.

Opposing photoelectric elements 15 ₁ , 15 ₃ , photoelectric elements 15
The sensing coils 16 and 17 detect the potential difference caused by the difference in the amount of light incident on _{the 2} and 15 ₄ , and the current is amplified by the amplifier 13' to drive the motors 6 and 7 and apply it to each reflector. The position of the sun is tracked so that the amount of light incident on the opposing photoelectric elements 5 ₁ and 5 ₃ and the photoelectric elements 5 ₂ and 5 ₄ is balanced, and at the same time, the attitude of the reflector 1 at each stage is controlled. The incident angle and reflection angle of the sunlight S with respect to the mirror surface 1a are adjusted, and the reflected light S' of the sunlight S received by each reflector 1 is concentrated on the shaded area d. In the two embodiments, 18 is a photosensitive circuit breaker which forcibly turns on the amplifiers 13 and 13' after sunset.
This is to stop the operation of the

According to the present invention, the support mechanism is driven by the attitude control mechanism 11 in response to changes in the position of the sun that change from moment to moment, and the reflector 1 at each stage is set in the attitude required to irradiate the shaded area with reflected sunlight. is adjusted, and the reflected light from the plurality of reflectors is irradiated onto the shaded area d all at once.

Therefore, during the period from sunrise to sunset, the reflected light S' of the sunlight S is irradiated onto the shaded area d with a strong light intensity, and the shaded area d is eliminated.

[Effect of idea]

As described above, according to the present invention, by using a plurality of reflectors supported vertically in parallel, sunlight reflected from the mirror surfaces of each stage of reflectors is powerfully irradiated onto shaded areas. Can eliminate shade. In addition, since the angle between the incident angle and the reflection angle of sunlight on each stage of reflectors is set relatively small, it does not require an excessive amount of space for installation, unlike when reflectors are arranged horizontally. It can be easily installed on the roof of a building by making effective use of the space above. Furthermore, in terms of structure, the motor can be shared for one shaft of the drive mechanism, thereby simplifying the structure.

[Brief explanation of drawings]

Figures 1A and 2B are perspective views showing the basic configuration of the shade eliminating device according to the present invention, Figure 2A is an explanatory diagram showing the installation procedure of the shade eliminating device according to the present invention, and Figure 2B shows the configuration of the device according to the present invention. Perspective views shown in Figure 3, Figure 4 A,
B is a configuration diagram of the attitude control mechanism. 1... Reflector, 1a... Mirror surface of the reflector, 2...
Support for reflector, 6, 7...Motor, 11...Attitude control mechanism.

Claims (1)

[Scope of claim for utility model registration] A plurality of reflectors each having a mirror surface that illuminates a shaded area with reflected sunlight, a support mechanism for the reflectors,
A shade eliminating device having a driving device for each reflector and an attitude control mechanism for controlling the attitude of the reflector, wherein the reflectors are arranged parallel to each other in upper and lower stages at predetermined intervals, and each of the reflectors is attached to a support mechanism. The support mechanism supports the reflector at each stage so as to angularly displace it around the horizontal axis (x-axis) and vertical axis (y-axis), and the drive device supports the reflector at each stage. The attitude control mechanism consists of a motor that rotates each of the reflectors in the forward and reverse directions around the x-axis, and a motor that rotates the support mechanisms that support the reflectors at each stage forward and backward around the y-axis. A sun tracking command is issued based on the position detection signal or data regarding the sun's position, and each motor of the drive device is rotated around the x-axis and y-axis, and the sun's rays incident on the reflector at each stage are shaded. A shade eliminating device characterized by controlling the posture of a reflector to an angle necessary for reflecting light to a certain area.