JPS58122785A - Method of solar energy collection and utilization - Google Patents

Abstract

PURPOSE:To synthetically utilize the solar energy by a method wherein the solar energy of thermic rays including the infrared ray i.e. a long wavelength band is caught as the heat and utilized for the energy to provide an accumulator with a fixed temperature, and while the solar energ in a short wavelength band such as visible light rays or ultraviolet rays is caught as the electric power and utilized. CONSTITUTION:A plurality of glass plates including more than one thermic ray absorbing glass plate 1 are arranged in parallel at intervals several mm.-several ten mm., and the peripheries thereof are sealed by using a sealing material 4 of teflon, nylon, rubber, etc. Further, a coolant supply port 5 is provided under the sealing material 4 or the glass plate 1, and an exhaust port not illustrated is provided above, then a flow rate adjuster 11 is connected to the accumulator 12 via a pipe 6 therebetween. On the other hand, in front of the glass plate 1, a photocell 9 is provided and connected to the accumulator 12 by using wire leads. Thus, the themal energy into the photocell 9 is cut off resulting in the enhancement of the conversion efficiency of the photocell 9, and the solar energy is synthetically utilized in effectivity by catching also the thermal energy.

Description

【発明の詳細な説明】 本発明は太陽光線を分離して有効に光ふよび熱エネルギ
ーを収集および利用する方法に関するものである。DETAILED DESCRIPTION OF THE INVENTION The present invention relates to a method for separating sunlight to effectively collect and utilize light and thermal energy.

太陽エネルギーの利用は、光エネルギー（口■視光紛お
よび紫外線等の波長の短かい域の利用）と熱エネルギー
（赤外線を含む熱線の波長の長い域の利用）の２通りが
あり、前者は太陽電池、後者は太陽熱利用温水器、太陽
熱発電等に応用されている。There are two ways to use solar energy: light energy (use of short wavelength range such as visible light and ultraviolet rays) and thermal energy (use of long wavelength range of heat rays including infrared rays). Solar cells, the latter being applied to solar water heaters, solar thermal power generation, etc.

従来、これらの応用は光エネルギーまたは熱エネルギー
のいずれか一方の応用にとどまっており、太陽エネルギ
ー範囲の一部を利用しているにすぎない。したがって、
太陽エネルギーの大半は利用されず、特に、光電池によ
り発電される光−変侠効率はこの中の約１０％にすぎず
、残りの９０％は熱となって放出されるだけでなく、光
′４池に熱エネルギーが供給されるために、それによる
温度上昇によって光電ｆｌ＆効率を向上させることかで
きなかった。Traditionally, these applications have been limited to either light energy or thermal energy applications, making use of only a portion of the solar energy range. therefore,
Most of the solar energy is not utilized, and in particular, the light-transfer efficiency generated by photovoltaic cells is only about 10% of this, and the remaining 90% is not only emitted as heat but also as light. Since thermal energy is supplied to the four ponds, the photovoltaic fl&efficiency could only be improved by the resulting temperature rise.

他方、光４池から得られる１気エネルギーを蓄える蓄電
池を所定の温度に保ったＶの示針のエネルギーを使って
いた。例えば鉛蓄電池は、他の手段で加熱され温度調節
された室内に８１１することにより所定の作動温直重こ
保たれている。On the other hand, the energy of the V indicator was used by keeping a storage battery that stored 1 ki energy obtained from the Hikari 4 pond at a predetermined temperature. For example, lead acid batteries are maintained at a predetermined operating temperature by placing them in a temperature-controlled chamber that is heated by other means.

本発明は上記に鑑みて、赤外線を含む熱縁いわゆる長波
長帯の太陽エネルギーを熱として捕えて、蓄（池を所定
の作動温度に保ったりのエネルギーとして利用し、かつ
可視光線または紫外線いわゆる′Ｉｋ１波長帯の太陽エ
ネルギーを電力として捕え、それぞれのエネルギーをゼ
効利用するとともに、光電池への熱エネルギーの供給を
遮断して光電池の変侠効率の同上を計り、太陽エネルギ
ーのｆ換効牟を−ＶるたＶの太陽エネルギーの収集およ
び利用方法を提案したものである。In view of the above, the present invention captures solar energy in the so-called long wavelength band including infrared rays as heat and utilizes it as energy for storing (keeping a pond at a predetermined operating temperature), and also uses visible light or ultraviolet rays, so-called In addition to capturing solar energy in the Ik1 wavelength band as electric power and effectively utilizing each energy, we also cut off the supply of thermal energy to the photovoltaic cells to measure the conversion efficiency of the photovoltaic cells and increase the f conversion efficiency of solar energy. - V This is a proposal for a method for collecting and utilizing solar energy from RutaV.

以下、図面を参照して本発明を説明する。The present invention will be described below with reference to the drawings.

第１図は本発明のｓｌの実施例を示す斜視図、第２図は
後述するその熱線吸収器材の断面図である。同図に示す
弗１の実施例においては、例えば熱ｍ吸収ガラス板ｌを
１枚以上含む複数校のガラス板を畝履乃至畝１０■間隔
で平行に並べ、その周辺部をシール材４例えばテフロン
、ナイロンおよびゴム等によりシールしている。さらに
、このシール材４または熱線吸収ガラス板ｌの下方に冷
却媒体供給口５を設け、またその上方に図示しない冷却
媒体排出口を設けて構成される赤外線を含む熱線を吸収
する器材（以下、熱線吸収器材という。）１Ｇを光電池
９の受光面側に密層または離して配置している。FIG. 1 is a perspective view showing an embodiment of the SL of the present invention, and FIG. 2 is a sectional view of the heat ray absorbing device described later. In the embodiment of the membrane 1 shown in the same figure, for example, a plurality of glass plates including one or more heat absorbing glass plates l are arranged in parallel at intervals of 10 to 10 ridges, and the periphery thereof is covered with a sealing material 4, for example. Sealed with Teflon, nylon, rubber, etc. Furthermore, a device (hereinafter referred to as (referred to as a heat ray absorbing device) 1G are arranged in a dense layer or spaced apart on the light-receiving surface side of the photovoltaic cell 9.

上記シール材４でシールされる空間に水または油等の冷
却媒体を通過させ、ＩＩ＆線吸収器材ｌＯ内に放散され
た熱を図示しない冷却媒体排出口に償続されるバイブロ
より取り出し、その熱は温度−節するたりの流量調節器
１１を介し、バイブロを通して蓄電池１２に加えられ、
これより排出される冷却媒体は再びバイブロを通して冷
却媒体供給口５に戻される。この蓄電池１２は上述した
光電池９から得られる１気エネルギーを蓄えるたＶのも
のであって、熱線吸収器材ｌＯ内に放散された熱によっ
て所定の作動温度範囲に加熱保温されている。一方、こ
れらの熱線吸収ガラス板ｌを透過した可視光線および紫
外線等の波長の短かい光線を光電池９に蕉射して感応さ
せる。この場合、光電池９には赤外！ｌＩを含む熱線か
ほとんど供給されないので、光電池は熱エネルギーによ
る温度上昇がな（、したがって光電変侯効率も向上する
。A cooling medium such as water or oil is passed through the space sealed by the sealing material 4, and the heat dissipated in the II & radiation absorption device 1O is extracted from a vibro connected to a cooling medium outlet (not shown). is added to the storage battery 12 through the vibro through the temperature-control flow rate regulator 11,
The coolant discharged from this is returned to the coolant supply port 5 through the vibro again. This storage battery 12 is a V battery that stores the 1 q energy obtained from the photovoltaic cell 9 described above, and is heated and kept within a predetermined operating temperature range by the heat dissipated within the heat ray absorbing device IO. On the other hand, short-wavelength light rays such as visible light and ultraviolet light transmitted through these heat-absorbing glass plates 1 are irradiated onto the photovoltaic cell 9 to sensitize it. In this case, the photocell 9 has infrared light! Since almost no hot wire containing lI is supplied, the photovoltaic cell does not experience a temperature rise due to thermal energy (therefore, the photovoltaic conversion efficiency also improves).

ｅ＃、蓄−４池１２と冷却媒体供給口５との聞に図ボし
ない熱交換器等を設置することにより、蓄電池の２１Ｉ
ＰＩ＆保温後の排熱を空調に利用することができる。ま
た、冷却媒体排出口と流量ａ１！Ｂ器１１との間にバイ
パス回路を設けて、冷却媒体をバイパスさせる図示しな
い蓄熱槽を設置して、その中に＆４池を埋設させるか、
または蓄−池の周囲に黙谷蓋の大なる材料を付加するこ
とによって、少々太陽光か欠けたとしても、適当な時間
、蓄電池を所定の作動温度範囲に保温することができる
。e#, by installing a heat exchanger, etc., which does not have any markings, between the storage battery 12 and the cooling medium supply port 5, the storage battery's 21I
Exhaust heat after PI and heat retention can be used for air conditioning. Also, the cooling medium outlet and flow rate a1! A bypass circuit is provided between the B unit 11 and a heat storage tank (not shown) that bypasses the cooling medium, and the &4 pond is buried therein, or
Alternatively, by adding a large piece of material around the storage battery, the storage battery can be kept warm within a predetermined operating temperature range for an appropriate amount of time even if there is a slight lack of sunlight.

第３図は本発明の第２の実施例を示す斜視図、！＠４因
は後述するその熱線吸収器材の断面図である。第２°の
実施例においては、例えば熱線吸収ガラス板１を２枚畝
諷乃至ｆｆ１ｌＯ腸の第１の間隔で平行に並べ、その両
側に２■乃至５■のｊＢ２の間隔を保持して平行に例え
ば通常の透明ガラス板２が並べられている。したがって
、この第２の間隔は熱線吸収ガラス板ｌおよび透明ガラ
ス板２によって形成されることになり、その周辺部はガ
ラス板７の溶層によりシールされて、そのシールされる
空間は真空状ｔｈ＆ｃ保たれている。また、弗１の間隔
は２枚の熱線吸収ガラス板１によって形成されることに
なり、その周辺部はシール材４、例えばテフロン、ナイ
ロンまたはゴム等によりシールして、このシール材４の
下方に冷却媒体供給口５およびその上方に図示しない冷
却媒体排出口を設けて構成される熱線吸収器材１ｏを光
電池９の受光面側に密層または離して配置している。FIG. 3 is a perspective view showing a second embodiment of the present invention. @4 factor is a cross-sectional view of the heat ray absorbing device described later. In the second embodiment, for example, two heat ray-absorbing glass plates 1 are arranged in parallel at the first interval of ridges to ff1lO, and the two sheets are arranged in parallel with a distance of jB2 of 2 to 5 on both sides. For example, ordinary transparent glass plates 2 are arranged. Therefore, this second interval is formed by the heat ray absorbing glass plate l and the transparent glass plate 2, and the peripheral portion thereof is sealed by the melt layer of the glass plate 7, and the sealed space is in a vacuum state th&c. It is maintained. In addition, the gap between the membranes 1 is formed by two heat-absorbing glass plates 1, and the periphery thereof is sealed with a sealing material 4, such as Teflon, nylon, or rubber. A heat ray absorbing device 1o, which includes a cooling medium supply port 5 and a cooling medium discharge port (not shown) above the cooling medium supply port 5, is arranged in a dense layer or spaced apart on the light receiving surface side of the photovoltaic cell 9.

上記シール材４でシールされる空間に、水または油等の
冷却媒体を通過させ、熱線吸収器材１０円に放射された
熱を真空層により外部への伝導を防止して有効に取り出
し、その熱を第１の実施例と同様に蓄電池の加熱保温用
として用いる。一方これらの熱線吸収ガラス板１を透過
した”Ｊ視光蛛および紫外線等の波長の短かい光線を光
電池９に照射して感応させる。A cooling medium such as water or oil is passed through the space sealed by the sealing material 4, and the heat radiated to the heat ray absorbing device is effectively extracted by preventing conduction to the outside with a vacuum layer. is used for heating and insulating the storage battery in the same way as in the first embodiment. On the other hand, the photovoltaic cell 9 is irradiated with short-wavelength light such as ultraviolet light that has passed through the heat-absorbing glass plate 1 and is made to sensitize it.

なお、′ｓ２の実施例において第２の間隔は、熱縁吸収
ガラス板と通常の透明ガラス板とにより形成されている
が、上記の通常の透明ガラス板の代りに上記の熱ＩＩ！
吸収ガラス板を用いてもよい。さらに、上記の透明ガラ
ス板によって前列した第ｌの間隔を形成するような構造
の熱線吸収器材であってもよい。Note that in the embodiment 's2, the second interval is formed by a heat edge absorbing glass plate and a normal transparent glass plate, but instead of the normal transparent glass plate, the heat II!
Absorbing glass plates may also be used. Furthermore, the heat ray absorbing device may have a structure in which the above-mentioned transparent glass plate forms the first interval in the front row.

第５図は本発明の第３の実施例を示す斜視図、第６鮪は
俊述するその熱線吸収器材の断面図である。第３の実施
例においては、光電池に最も適した光−資産を得るた０
にレンズ８を用い、かつレンズ８の受光面と例えば熱線
吸収ガラス板ｌとを献■乃至畝１０膳間隔で平行に並べ
、その周辺部をシール材４例えばテフロン、ナイロンま
たはゴム等によりシールして、このシール材４または熱
＃Ｍ吸収ガラス板ｌの）方に冷却媒体供給口５およびそ
の上方に図示しない冷却媒体排出口を設けて構成される
熱線吸収器材ｌＯを光電池９の受光面側にを４または離
して配置している。FIG. 5 is a perspective view showing the third embodiment of the present invention, and No. 6 is a sectional view of the heat ray absorbing device described in detail. In a third embodiment, in order to obtain the most suitable light-asset for photovoltaic cells,
The light-receiving surface of the lens 8 and, for example, a heat ray-absorbing glass plate L are arranged in parallel at intervals of 10 or 10 ridges, and the periphery thereof is sealed with a sealing material 4, such as Teflon, nylon, or rubber. Then, a heat ray absorbing device 10, which is configured by providing a cooling medium supply port 5 and a cooling medium discharge port (not shown) above the sealing material 4 or the heat #M absorbing glass plate 1), is placed on the light receiving surface side of the photovoltaic cell 9. They are placed 4 or more apart.

上記シール材４でシールされる空ｒｗＪに水または油等
の冷却媒体を通過させ、熱線吸収器材１０内に放散した
熱を取り出し、その熱を第ｌの実施例と同様に蓄４＃！
の加熱保温用として用いる。−万、これらの熱線吸収ガ
ラス板ｌを透過した可視光縁および紮外巌等の波長の短
かい光醸を光電池９になお、ｍｌおよび１１ｇ２の実施
例において、し／ズを熱線吸収器材の受光面側のガラス
板に密１させるか、または第２の実施例において上記ガ
ラス板の代りにレンズを用いてもよい。A cooling medium such as water or oil is passed through the air rwJ sealed by the sealing material 4, and the heat dissipated in the heat ray absorbing device 10 is extracted, and the heat is stored in the same manner as in the first embodiment.
Used for heating and keeping warm. - In addition, in the examples of ml and 11g2, the light with short wavelengths such as the visible light edge and the light beam transmitted through the heat ray absorbing glass plate 1 is transferred to the photovoltaic cell 9. The glass plate on the light-receiving surface side may be closely spaced, or a lens may be used in place of the glass plate in the second embodiment.

以上のように本発明の太陽エネルギーの収束および利用
方法によれば、太陽エネルギーを効率よく熱エネルギー
と光エネルギーとに分畷して１．１ｔ１４をそれぞれ有
効に利用することができ、光ｍ１ｔｔ！を温度上昇させ
る熱エネルギーまでも吸収して、鉛蓄電池はもちろんの
こと、適正な高温の作動ＩＭＰ！Ｌを維持する必要性が
特にある蓄電池、例えば近ヰ実用化されたナトリウム・
イオウ系電池、聰＾・リチウム系電池等にその熱エネル
ギーを供給して、熱エネルギーとして有効に利用するだ
けでなく、光電池に供給される熱エネルギーを遮へいし
て光電池の熱エネルギーによる温度上昇を防止すること
によって、光電池の光域変換効率を同上させ、かつその
劣化２よび破損をも防止することかできる。このように
、光電池、蓄電池および熱ＮＵ収器材等を組合せること
によって、太陽エネルギーの総合的有効利用およびこれ
らの器材の信頼性の向上番こ役立つ。As described above, according to the solar energy convergence and utilization method of the present invention, solar energy can be efficiently divided into thermal energy and light energy, and 1.1t14 can be effectively used, and the light m1tt! It absorbs even the thermal energy that increases the temperature of the IMP, allowing it to operate at appropriate high temperatures not only for lead-acid batteries! Storage batteries that have a particular need to maintain L, such as sodium batteries that have recently been put into practical use
In addition to supplying the thermal energy to sulfur-based batteries, lithium-based batteries, etc. and using it effectively as thermal energy, it also shields the thermal energy supplied to the photovoltaic cells and prevents the temperature rise due to the thermal energy of the photovoltaic cells. By preventing this, the light range conversion efficiency of the photovoltaic cell can be increased as well as its deterioration 2 and damage can be prevented. In this way, by combining photovoltaic cells, storage batteries, thermal NU collection equipment, etc., the overall effective use of solar energy and the reliability of these equipment can be improved.

【図面の簡単な説明】[Brief explanation of drawings]

第ｌ乃至第６図は、本発明の太陽エネルギーの収集およ
び利用方法の実施例を示す図であって、第１図、第３図
および第５図は斜視図、第２図、４４図および第６図は
それぞれの熱線吸収器材の断面図である。 ９・・・光電池、ｌＯ・・・赤外縁を含む＃ｉ＆線を吸
収する器材、１２・・・蓄電池。 代理人　弁理士　　中　井　　　　宏 手　続　補　正　書　（自発） 昭和５７年　２月１５日 特許庁長官殿 特願昭５７　−５２８５　　　号 ２　発明の名称 太陽エネルギーの収集および利用方法 ３　補正する者 事件との関係　　特許出願人 （０２６）大阪変圧器株式会社 屯代理人 住　所　　〒５３２大阪市淀川区田用２丁目１番１１号
５　補正の対象 １図面」 ６　捕市の内容1 to 6 are diagrams showing an embodiment of the solar energy collection and utilization method of the present invention, in which FIGS. 1, 3, and 5 are perspective views, and FIGS. 2, 44, and 5 are perspective views. FIG. 6 is a sectional view of each heat ray absorbing device. 9... Photovoltaic cell, lO... Equipment that absorbs #i& rays including the infrared edge, 12... Storage battery. Agent: Hiroshi Nakai, Patent Attorney Continuation of amendment (spontaneous) February 15, 1980 Patent Application No. 1983-5285 to the Commissioner of the Japan Patent Office Title of invention Method of collecting and utilizing solar energy 3 Case of the person making the amendment Relationship with Patent Applicant (026) Osaka Transformer Co., Ltd. Agent Address: 5-2-1-11 Tagyo, Yodogawa-ku, Osaka 532 1 Drawing Subject to Amendment 6 Contents of the Complaint

Claims (1)

【特許請求の範囲】[Claims] １、太陽光の下で動作する光電池の受光面側に赤外線を
含む熱線を吸収する器材を配置し、前記器材内に冷却媒
体が通過する空間を設けて、ｏｉＩ記器材を冷却した熱
を用いて前記光電池から得られる４気エネルギーを蓄え
るたのの蓄電池を所定の作動温度にＪ熱保温するととも
に、赤外線を含む熱線が除去された有効な光線だけを光
電池に照射させる太陽エネルギーの収集および利用方法
。1. A device that absorbs heat rays including infrared rays is placed on the light-receiving surface side of a photovoltaic cell that operates under sunlight, and a space is provided within the device for a cooling medium to pass through, so that the heat generated by cooling the oiI device is used. Collecting and utilizing solar energy by heating the storage battery to a predetermined operating temperature and irradiating the photovoltaic cell with only effective light from which heat rays including infrared rays have been removed. Method.