JPS60107871A - Film body power generator utilizing solar battery - Google Patents

Abstract

PURPOSE:To improve durability while simplifying installation by a method wherein solar batteries are fixed on a flexible film bodies which are developed to form a generator. CONSTITUTION:A film body power generator 10 is composed of a film surface structure provided with multiple film bodies 11 of relatively large area bonded with one another while this reinforced with multiple flexible nets 18 connected with one another is formed on the bases 19. Multiple spaces 13 are formed by transparent films 12 on the film bodies 11 while solar battery modules 17 are contained in the spaces 13 so that they may not be dynamically coupled with the film bodies 11 and the transparent film 12 in terms of the elongation of the modules 17. The transparent films 12 may make the performance of the solar batteries 14 effective.

Description

DETAILED DESCRIPTION OF THE INVENTION (Technical Field) The present invention relates to a membrane power generation device using solar cells. In the following description, a solar cell refers to the smallest medium cell, and a solar cell module refers to a medium formed by these solar cells.

(Prior Art) Although solar cells have been increasingly used in recent years, there are still many points to be improved. For example, in order to obtain a predetermined electromotive force with a solar cell, it is necessary to spread the solar cell over a relatively large area.

In order to securely install solar cells in such a large area, taking into account their durability, a specified structure is formed using concrete and a large amount of steel, and this structure is Thousands of solar cells would have to be installed. However,
Solar cells are usually installed in places that people cannot visit many times, such as isolated islands, deserts, and deep mountains, and the work required to install solar cells in such places is extremely difficult. Have difficulty. That is, in order to install solar cells, not only must a large amount of concrete and steel materials be transported to the location in advance, but the work must also be carried out in a difficult location.

These things themselves are difficult business to begin with.

Fortunately, however, recent improvements have been made to the structure of solar cells. In other words, by placing solar cells on a thin and flexible stainless steel substrate or polyester film substrate, a solar cell module (unit or φ piece) that is flexible can be manufactured. It has become.

(Item 9) The present invention has been made in view of the above circumstances, and
The purpose is to provide a membrane power generation device using solar cells that is not only highly durable, but also extremely easy to install and can be completed at low cost. (Structure) In order to achieve such an object, the present invention attaches solar cells on a film body made of flexible rags 1, electrically connects each solar cell, and connects the 1 model to JJ. The gist of the invention is a membrane power generation device using a solar cell, which is characterized in that it is formed by opening the membrane.

(Example) An embodiment of the present invention will be described below with reference to the drawings. Fig. 1 shows a membrane power generation device (hereinafter simply referred to as a membrane power generation device 1t) (10 ) is shown in a perspective view. This one-model power generation device (lO) has a large number of membrane bodies (11) joined together to form one membrane structure having a relatively large area, and this membrane structure has flexibility. A base (18) reinforced with nets (18) to (18) etc. and installed on the ground, etc.
19) Formed by connecting above. In addition,
A wire connection (20) is taken out from a part of this membrane power generation device (10), and a capacitor (21) is connected through this wire connection (20).
) and a working device (22) are connected.

As shown in FIG. 2, each membrane body (11) is for providing a large number of solar cells (14) on its L side,
It has a certain degree of flexibility. In other words, this one mock holiday (11
), as shown in Figures 3 and 4, the fabric (1l
It has a hybrid configuration in which a coating material (llb) is applied to a). The coating material (i+b) is a polymeric material 1 having mature IJ plasticity, such as polyJΣ11.
It is preferable to use vinyl chloride, tetrafluoroethylene, etc. Moreover, as shown in FIGS. 2 to 4, a large number of spaces (13) are formed on the upper surface of this film body (11) by a transparent film (12), and these spaces (13) Inside, two solar cell tops (17), which will be described later, are housed in one model (11) and a transparent film (12) so as not to be mechanically bonded to their elongation. This transparent) flum (
12) has the following properties. That is, this transparent film (12) is placed 11 degrees inside the solar cell (14) in order to enable the solar cell (14) to function effectively as described below. In order to avoid reducing the power generation efficiency of the solar cell (14) by absorbing the light energy that enters the body or reflecting it to the outside, the transparency must be sufficient to ensure that the sunlight passes through the solar cell (14). It is a ghost that it has a certain flexibility. Suitable materials include polyester films and the like. This transparent film (12) is partially bonded onto the above-mentioned film body (11) by heat welding or adhesive. This forms a space (13) that accommodates the solar cell (14). Now, the formed membrane body (11) is subjected to external pressure such as wind. This external pressure causes the bent body (11) to bend. Even if this bending occurs, the solar cell module (17) will not be damaged because it has flexibility as described above. on the other hand,
As this bending occurs, one model (11) stretches. Therefore, as described above, the transparent film (12) partially bonded to the 119 body (11) also extends integrally with the membrane body (11). Even in such a case, as described above, the solar cell module (17) should be prevented from being mechanically coupled to the expansion of the membrane (11) or transparent film (12) in the space (13). Since the solar cell module (17) is housed in a straight line, the solar cell module (17) does not extend as a whole. In this way, the membrane body (11) and the transparent film (12)
Even if external pressure such as wind that causes elongation acts on the solar cell module (17), the solar cell module (17) will not be stretched and damaged.

As shown in FIG. 5, each solar cell (14) is mounted on a thin and flexible stainless steel or polyester substrate (14a), thereby forming one solar cell module (17). ).

Further, each solar cell (14) is electrically connected by a wire connection (15). The solar cell module (1?) formed in this way is made of a stainless steel substrate or a polyester substrate 2,
f Even if the relative position of each solar cell (14) changes due to flexibility, each connection (15) connecting these solar cells (14)
This prevents the solar cells (14) from burning out or impairing the functions of each solar cell (14). And, this solar cell module (17) has limbs (11) )-trans'
JJ7 - “Each space formed by Lum (12) (
13). It should be noted that the storage of the solar cell M-2 Neil (17) is carried out at the same time as the membrane body (11) and the transparent film (12) are bonded.

In addition, each connection (15) is connected by a connector (16) as shown in Fig. 3, and is ultimately connected to the connection (20) shown in Fig. 1. It is.

(Action and effect J)! :) In the membrane power generation device (IO) configured as described above, the installation work is very easy. That is, form the base (one) shown in Fig. 1 on the ground or the like at the installation location, and attach the end of the rope (18) of the IM membrane power generation device 1O) to this base (19) by connecting it to the LL1. ! All you have to do is tie it. Since each base (19) is for connecting the ends of the rope (18), there is no need to form it as a large structure, and the membrane power generation device (IQ) has a predetermined size. There is no need to carry out these operations at the installation site, since it is sufficient to form the device as an object. In addition, since each base (18) does not need to be very large, there is no need to transport large quantities of materials required for its construction. Since it is only necessary to attach it using the rope (18), it is sufficient for each base (18) to be of a size that allows the membrane power generation device (lO) to be removed. . Therefore, in the installation work i and yi of this M-body power generation device (lO), each base (18) is
10) using the rope (18), the connection L'i-r is good, so the setup of this membrane power generation device (lO);
Not only can the work be done easily, but the cost of the membrane power generation device (IO) itself can be reduced.

As described above, the membrane power generation device (lO) expanded and attached to the valley base (19) will naturally be subjected to the force of the wind. However, this 112 idle power generator (1
0) is 119 each! body H+), transparent film (12)
, the substrate (14a) of the solar cell (14) and each #11 (
18) are all flexible, so even if they move somewhat awkwardly, this will not impair their function as a power generating device. Particularly, the solar cell module (17) in which a plurality of solar cells (14) are fabricated is Even if the position changes, each connection (15
) is 9J, each sun 'i'Li: rtl (14
) is designed to ensure that the functionality of the device is not impaired. Also, Taiyo'Kamiike Mozoyur (17
) is housed in such a way that the IIA body (11:' and transparent) in the space (]3) and the stretcher in the f lume (12) are not mechanically connected, so they cannot be stretched. No damage. Therefore, it can also be said that this membrane power generation device (10) has excellent durability.

(Summary) As detailed above, in the present invention, as exemplified in the above embodiment, solar cells are attached to a membrane body having df flexibility, each solar cell is electrically connected, and ,
The feature lies in the fact that the membrane is formed by expanding it, which not only makes it highly durable, but also makes it possible to create solar cells that are extremely easy to install and can be manufactured at low cost. It is possible to provide a membrane power generation device using the above method.

[Brief explanation of drawings]

Fig. 1 is a perspective view of a membrane power generation device according to the present invention, Fig. 2 is a partially enlarged perspective view showing the lower part of Fig. 1, and Fig. 3 is a partially enlarged perspective view showing the yellow part of Fig. 2-. Figure 4 is the IV of Figure 3.
FIG. 5 is a partially enlarged vertical sectional view taken along line -IV, and a perspective view showing the solar cell module. Explanation of symbols 1O... Membrane power generation device, 11... Membrane body, 12...
Transparent film, 13... Space, 14... Solar cell,
14a... Board, 15... Connection, 16... Connector, 17... Solar cell module. Patent applicant Taiyo Kogyo Co., Ltd. Agent

Claims (1)

[Claims] A solar cell is attached to the membrane body 1- which has flexibility, and each solar cell is electrically connected to the membrane body +M.
A membrane power generation device using a solar cell, characterized in that it is formed by opening.