JPS58120203A - Solar ray gathering deivce - Google Patents

Abstract

PURPOSE:To turn a tracking system efficiently with a small torque, by providing two revolving shafts which support a convergent lens of solar rays, a gathering part, and a photoconductor for transmission freely rotatably as one body and tracking the sum by rotation of gears. CONSTITUTION:The light receiving terminal of the photoconductor is inserted to a hole P of a solar ray gathering part 19, and solar rays converged by a lens 11 are led to it. The rotation of a pulse motor 22 fixed onto a supporting arm 16 is transmitted to a large gear 24 through a small gear 23 to drive the first revolving shaft 14. A large gear 21 is attached to the second revolving shaft 17 and is driven through a small gear 20 by a motor 18. The convergent lens 11, the solar ray gathering part 19, and the photoconductor are turned as one body with a small torque by the rotation of revolving shafts 14 and 17 to track the sum efficiently through a solar ray sensor 12.

Description

DETAILED DESCRIPTION OF THE INVENTION The present invention relates to a solar light collection device, particularly a solar bar that efficiently collects sunlight by making the light-receiving surface of a lens system that focuses sunlight follow the movement of the sun. In the collection device, the tracking movement section including the lens system can be rotated efficiently with a small torque.

Figure 41 shows an implementation of the solar collector according to the present invention.
yl", in which 1 is a cylindrical base part, 2 is a cylindrical base part,
is a transparent dome-shaped head, which constitutes a capsule 3 for the solar collector, and in use, the solar collector 10 is housed within the capsule 3 as shown. This sunlight collecting lens 10 is composed of a large number of lenses (for example, 7 or 19 lenses) to focus the sunlight.
1. Sunlight direction sensor 12 for detecting the direction of the sun
, a support frame 13 that holds these together, a first rotation shaft 14 for rotating the support frame 13, and the rotation h 1
A support arm 16 for freely supporting 4 and a second rotation shaft 17 for rotating the support arm 16 about an axis perpendicular to the first rotation shaft 14, etc. The direction of the sun is detected by the sunlight direction sensor 12, and the rotation axis of the introduction 1 and the second rotation axis are controlled by the detection signal so that the lens 11 always faces the direction of the sun. The sunlight focused by the lens is introduced into a four-light conductor cable (as shown in the figure) whose light receiving end is placed at the focal point of the lens, and is transmitted to any desired location through the light guide cable. . Conventionally, in the solar light collecting device as described above, the first rotating shaft and the second rotating shaft are
Since the driving force is applied coaxially with the rotating shafts of the motors, these rotating shafts are subject to large flexures and cannot be driven smoothly. Particularly, in devices that follow the minute movements of the sun, such as the solar collector, a pulse motor (including a DC pulse motor) is used to follow the minute movements of the sun. When driving the motor, the shaft is added and the rotation axis is R as shown in Figure 2.
Furthermore, due to the inertia of the rotating parts, including the lens system, etc., as shown by T in Figure 3, the bending occurs as shown by S. The rotational force is not transmitted smoothly to the rotating shaft, and in the worst case, the rotating part may hunt, making it difficult to collect sunlight efficiently.

The present invention was made in view of the above-mentioned circumstances, and
FIG. 2 shows an enlarged view of the back surface of the solar MB of the solar collector according to the present invention, and FIG. 3 shows its side surface. In FIG. 2, reference numeral 19 denotes a sunlight collector t;li, and the light receiving end of a light guide (not shown) is inserted into the hole P of the sunlight collector 19, and the sunlight collector 19 is moved in the Y direction and the Y direction. Adjust the light receiving surface of the light guide to match the focus position of the lens.
directing sunlight focused by a lens into the light guide;
Through the light guide, it is transmitted to 1k of the world's wishes. Now, in FIGS. 2 and 3, 18.22 is a pulse motor, 20 is a small gear, 21.24 is a large gear, the large gear 21 is a substantially semicircular gear, and the gear 24 is the first gear. is attached to the rotating shaft 14 of the lens so that its teeth are on the back side of the lens (in other words, not exposed to the surface of the lens), and on the other hand,
A motor 22 for driving the gear wheel is fixed on the support arm 16, and the rotation of the motor 22 is transmitted to the large gear 24 through a small gear path to drive the first rotating shaft. ing. Further, the large wheel 21 is attached to the second rotating shaft 17 and is driven by the motor 18 via a small wheel.

In this way, according to the present invention, the first rotating shaft and the second rotating shaft are driven via a large-diameter steel wheel that is concentric with the rotating shaft. The bending and bending of the rotating portion can be suppressed, and therefore, the reaction caused by these bending and bending is eliminated, and stable follow-up operation can be performed. In the embodiment shown above, in order to drive the first rotating shaft 14, a substantially semicircular large-diameter gear 24, a small-diameter gear trap that meshes with the gear 24, and the gear B are used. The driving motor 22 is 1. ! ! Two sets (one pair) of drive mechanisms having the same construction as those used in the above-mentioned drive mechanism are provided symmetrically in the axial direction of the rotating shaft 14 in FIG. 1 with respect to the Y-Y' net. This is also possible, and in this way, the rotating part including the lens system 11 can be more stably supported and rotated. In addition, the second rotating shaft 17 is made of medium 2M construction, and the optical conductor cables attached to each sunlight collecting section 19 are placed along the supporting arm 16, and then the second rotating shaft 17 is By disposing it through the hollow part, the guide cable can run freely relative to the rotation of the first rotation shaft 14 and the second rotation shaft 17, and Even if the second rotation 4i11117 rotates, the optical conductor cable can be arranged so as not to become entangled with the rotating part.

FIG. 4 is a rear view showing another embodiment of the present invention. In this embodiment, a roller 34 is used instead of the approximately semicircular gear shown in FIG. 12, and a small diameter gear 2. A roller 33 is used in place of 3. By doing this, backlash, backlash, etc. that occur when using an In-wheel vehicle are eliminated.
The lens system 11 can be rotated more smoothly.

Note that 34a, 33a, and 32a are gears and motors that are provided symmetrically with the gear support and motor 32 with respect to the axial direction of the first rotating shaft 14, and thus drive the first rotating shaft 14. If a pair of actual movement mechanisms are provided symmetrically with respect to the axial direction of the first rotation axis, the rotating section including the lens system 11 can be more stably supported and rotated. Furthermore, when the driving rollers 33, 33a are made of an elastic body, the impact generated on the rotating portion when the pulse motor is driven can be absorbed by the elastic roller.

In addition, it is also possible to provide a support roller (idle roll) that supports the roller 34.34a separately from the drive roller, and when this support roller is provided, the roller 34. .34 There is no need to provide a support function to support the parts such as a, and therefore, even if an impact or the like occurs on the rotating part, the rotating part can be driven stably. In addition, in this embodiment, instead of the gears 20 and 21 shown in FIG. 2, a roller (9),
31 is used, but the embodiment shown in FIG.
In both the embodiments shown in the drawings, either gears or rollers may be used for this part, but as stated above, using rollers provides more stable driving. In addition, in FIG. 4, 40 is a light guide cable, and in the figure, the light guide cable is run along the support arm 16, and then
An example is shown in which the light guide cable is installed through the hollow part of the rotating shaft 17 of the tab 9, but in this way, the light guide cable can be inserted through the hollow part of the rotating shaft 17, regardless of the rotation of the rotating part. It can be arranged so that it does not get tangled. At that time, if the diameter of the second rotating shaft 17 is made large as shown in Figure 4, the bending of the second rotating shaft can be eliminated, which is convenient.

[Brief explanation of drawings]

FIG. 1 shows a solar power collecting device according to the present invention.
Figure 2 is an overall schematic configuration diagram for explaining 1J.
Enlarged rear view of the solar collector shown in the figure, third door I r
j X side 11] Figure i and Figure 4 are rear views showing other embodiments of the sunlight collecting device according to the present invention. 1 () Solar collector, 11... Lens, 12...
- Sunlight direction sensor, 13 - Support frame, 14... first
Rotation 'l'l11, +6・Support arm, 17・Second rotating shaft, 19・・Solar light collector, 18, n・・Pulse motor, 20, n・Small gear, 21. 24・・Big gear , side, 3
1.33.33a, 34.3.1a ・Roller, 40・
・Light guide. Figure 2 Figure 3 Figure 4

Claims (1)

[Scope of Claims] (1) A lens system for concentrating sunlight, and a sunlight collection unit configured integrally with the lens system and for collecting sunlight focused by the lens system; a first rotating member that rotatably supports a light guide for transmitting sunlight collected by the sunlight collection unit to a desired location; and a member integrally configured with the lens system and the plate lens system; a support arm that supports the first rotation shaft; and a second support arm that supports the support arm rotatably around an axis that is similar to the first rotation shaft.
a rotation axis, the first rotation axis and the second rotation axis 1;
In a sunlight collecting device, the f-axis is controlled so that the light-receiving surface of the lens system faces the sun, sunlight is introduced into the light guide, and is transmitted to any desired location through the crushed crab conductor, said first rotation +; bll (Y) a substantially semicircular large-diameter gear integrally attached to said rotating shaft and having teeth on the back side of said lens system, meshing with said gear and said support; and a small-diameter gear rotated by a motor, the rotation of which is controlled by the second rotating shaft. Its rotation is achieved by a large-diameter gear or roller that is integrally attached to the shaft and a small-diameter gear or roller that meshes or engages with the gear or roller and is rotated by a motor that is disposed on the fixed part. The solar light collection device according to claim (1), characterized in that: (3) the substantially semicircular large-diameter gear, the small-diameter gear that meshes with the gear; The sunlight according to claim 1 or 2, characterized in that a pair of motors for driving the small-diameter gears are provided symmetrically in the axial direction of the first rotating shaft. Collection device ρ (4) A patent characterized in that the second rotating shaft has a hollow structure, and the light guide is disposed along the supporting arm and through the hollow part of the second rotating shaft. The solar light collection device according to claim 1, 2, or 3. and a solar light collection unit that collects sunlight collected by the lens system, a light guide that transmits the sunlight collected by the sunlight collection unit, and is integrated with the lens system and the lens system. a first rotating shaft that rotatably supports the sunlight collecting section of the configuration, a support arm that supports the first rotating shaft, and a shaft that connects the supporting arm to the first rotating shaft. The second rotatably supported
a rotating field, the first rotation axis and the second rotation axis are controlled such that the light-receiving surface of the lens system faces the direction of the sun, sunlight is introduced into the light guide, and the light is In the solar collecting device configured to transmit sunlight to any desired location through a conductor, the first rotating shaft is integrally attached to the rotating shaft and is disposed on the = side of the lens system. The rotation of the roller is controlled by a substantially semicircular large-diameter roller and a small-diameter drive roller that engages with the roller and is rotated by a motor disposed on the support arm. Features of solar collection device. (6) The second rotating shaft is rotated by a large-diameter gear or roller that is integrally attached to the rotating shaft, and a motor that meshes or engages with the gear or roller and is disposed on the fixed part. Claim 1, wherein the rotation is controlled by a small-diameter gear or roller. ')1
The sunlight collecting part N described in Section 1. (Force) A pair of the substantially semicircular large-diameter roller, a small-diameter drive roller that engages with the roller, and a motor that drives the small-diameter roller are provided symmetrically in the axial direction of the first rotating shaft. Claims (5) or (6) characterized in that:
) The solar light collecting device described in item 1. (8) The substantially semicircular large diameter roller is supported by an idle roller and driven by the drive roller. The solar light collection device according to item 1 (9) Claims characterized in that the substantially semicircular large diameter roller is made of a copper body, and the drive roller and idle roller are made of an elastic body. 6.110) The second rotating shaft has a hollow structure, and the light guide is guided along the support arm and Claims (5) to (9) are characterized in that the second rotating shaft is disposed through the inner part of the shaft.
1. The solar light collecting device according to any one of the above items.