JP2016068028A - Method for cleaning solar thermal power generative reflector, cleaning system, solar thermal power generation system, and cleaning device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a method for cleaning a solar thermal power generative reflector, a cleaning system, a solar thermal power generation system, and a cleaning device, that use a gaseous matter instead of using washing water in cleaning a light reflection mirror reflecting sunlight and that carry out cleaning with little reflectance reduction of light to be collected, without causing damage to a surface of the light reflection mirror.SOLUTION: Provided is a cleaning method in which a gaseous matter is used for cleaning a solar thermal power generative reflector 20B comprising a light reflection mirror that has a surface layer whose water contact angle is within a range of 80 to 170° and that reflects sunlight. In the vicinity of the light reflection mirror, an air blowing device 40 and a dust collecting device 50 are disposed. Air is blown from the air blowing device 40 toward a surface of the light reflection mirror while at least one of either the air blowing device 40 and the dust collecting device 50 is moved on the surface of the light reflection mirror, and thereby deposit removed from the surface of the light reflection mirror by the blown air is collected utilizing the dust collecting device 50.SELECTED DRAWING: Figure 8

Description

  The present invention relates to a cleaning method, a cleaning system, a solar power generation system, and a cleaning device for a solar power generation reflecting device. More specifically, a method for cleaning a solar power generation reflecting device that cleans (cleans) a light reflecting mirror that reflects the sunlight provided in the solar power generation reflecting device with gas (including wind) without using cleaning water. Etc.

As a method of converting sunlight into energy, solar thermal power generation has been attracting attention, in which sunlight is reflected by a reflecting mirror and heat is generated by condensing light as a medium.
Since solar reflective mirror devices in solar thermal power generation are exposed to ultraviolet rays, heat, wind and rain, sandstorms, etc., glass mirrors with good weather resistance have been used conventionally. However, glass mirrors are highly durable to the environment, but they are damaged during transportation, and because they are heavy, it is necessary to increase the strength of the frame on which the mirrors are installed, which increases plant construction costs. In addition to the problem, it has become necessary to further reduce the cost of maintenance of the solar reflective mirror in order to further reduce the power generation cost.
In order to solve the problem of increasing the construction cost of the plant due to the heavy weight as mentioned above, it is necessary to increase the construction cost of the plant, replacing the glass light reflecting mirror with a resin light reflecting sheet. Is being considered.
However, when a metal such as silver is used for the light reflecting layer of the resin light reflecting mirror, there is a problem that silver is corroded when oxygen, water vapor, hydrogen sulfide or the like passes through the resin layer. In addition, since the resin layer is deteriorated by ultraviolet rays, causing problems such as discoloration and film peeling, improvements are being studied.

On the other hand, it was found that the dust dirt in the desert forms a strong sand film and sticks to the surface of the sunlight reflecting mirror, unlike ordinary dirt. This is because dust deposits on the mirror surface, and the condensation that occurs due to the large temperature difference between day and night adheres to the mirror surface, so that dust-containing substances (for example, NaCl, CaCO ₃ , SiO ₂ etc.) dissolved in the condensation, Contaminants in the atmosphere (such as SOX) react to produce insoluble salts, and then the water evaporates and the salt and sand particles aggregate to form a tight sand film. it is conceivable that.
The above-mentioned dust dirt causes a decrease in the reflectivity of the reflection mirror, deteriorates the power generation efficiency, and has been a problem when performing solar thermal power generation using a solar reflection mirror.
For this reason, it is necessary to periodically clean the mirror surface of the solar reflective mirror, but since a large number of thousands of solar reflective mirrors are installed on a vast site in a normal solar power generation facility, The cleaning work was a laborious and time consuming work. Therefore, in order to improve the cleaning work efficiency, a technique related to a cleaning robot system that can automatically clean the surface of a solar reflective mirror for solar power generation using cleaning water has been proposed (patent) Reference 1). In addition, there is a method using air blow as a method for removing dust and the like without using cleaning water (Patent Document 2).

However, in the case of the above-mentioned Patent Document 1, even if normal dirt can be cleaned by rubbing the mirror surface with a rotating brush in addition to the injection of water or the like, the peculiarity adhered firmly to the mirror surface of the sunlight reflecting mirror Measures are not taken to remove dust and dirt. Therefore, in order to clean the dust dirt, it is sometimes necessary to use a large amount of water and a cleaning liquid containing a surfactant or the like. In addition, it may be necessary to rub strongly using a rotating brush.If it is a resin reflecting mirror, it will not only scratch the mirror surface with the rotating brush, but it will also dent and reflect the reflectance. There was a risk of lowering.
Because of such cleaning, cleaning methods that use a large amount of precious water in the desert may increase maintenance costs due to the use of precious water in the desert. Since there is no drainage facility in the desert where it is installed, if there is no drainage facility in the desert, there is a risk of causing environmental destruction.

  On the other hand, in Patent Literature 2, dirt is removed by blowing air from a cleaning device without using cleaning water. However, deserts where sunlight reflecting mirrors where water is precious are installed are dry, and the deposits can be removed by blowing as in the present invention, but the surface of the sunlight reflecting mirror is strongly charged by blowing. As a result, the dirt that was blown away was once again electrostatically attached. As a result, the problem was that the light reflectance was lowered.

Japanese Patent No. 4477685 JP 2010-58058 A

  In light of the above problems, the solution is to use gas instead of cleaning water to clean the light reflecting mirror that reflects sunlight, and to collect light without scratching the surface of the light reflecting mirror. A cleaning method, a cleaning system, a solar thermal power generation system, and a cleaning device for a solar thermal power generation reflection device that can perform cleaning with little reduction in the reflectance of light.

As a result of intensive studies in view of the above problems, the present inventor has found that a light reflecting mirror having a specific water contact angle can be efficiently cleaned with a gas (including wind) instead of cleaning water. It came to. That is, the said subject which concerns on this invention is solved by the following means.
1. It is a cleaning method for a solar thermal power generation reflection device that cleans with a gas a solar power generation reflection device that includes a light reflection mirror that reflects sunlight having a surface layer with a water contact angle in the range of 80 to 170 °. ,
A blower and a dust collector are provided near the light reflecting mirror,
While moving at least one of the blower and the dust collector on the light reflecting mirror surface,
The solar power generation reflecting device according to claim 1, wherein the dust collecting device collects deposits removed from the light reflecting mirror surface by blowing air from the air blowing device toward the light reflecting mirror surface. Cleaning method.

2. 2. The method for cleaning a solar power generation reflecting device according to claim 1, wherein the light reflecting mirror has a light reflecting layer on a resin base material.

3. The devices that move on the light reflecting mirror are the blower device and the dust collector, and at least one device that moves on the light reflecting mirror has a static eliminator, and moves while neutralizing the surface of the reflective mirror. A cleaning method for a solar thermal power generation reflecting device according to item 1 or 2.

4). The cleaning method for a solar power generation reflecting device according to any one of claims 1 to 3, wherein a wind speed of the air discharged from the air blowing device is 5 to 80 m / s.

5. A solar power generation reflecting device cleaning system for cleaning a light reflecting mirror that reflects sunlight provided in a solar power generation reflecting device with gas,
The light reflecting mirror has a surface layer whose water contact angle is in the range of 80 to 170 °,
A blower and a dust collector are provided near the light reflecting mirror,
While moving at least one of the blower and the dust collector on the light reflecting mirror surface,
The solar power generation reflecting device according to claim 1, wherein the dust collecting device collects deposits removed from the light reflecting mirror surface by blowing air from the air blowing device toward the light reflecting mirror surface. Clean system.

6). A solar thermal power generation system having a plurality of light reflecting mirrors for reflecting sunlight and a cleaning device for cleaning the surface of the light reflecting mirror,
The cleaning device has a water contact angle on the surface of the reflection mirror in the range of 80 to 170 °, and has a blower and a dust collector for installation near the surface of the reflection mirror,
While moving at least one of the blower and the dust collector on the light reflecting mirror surface,
The solar power generation system, wherein air is blown toward the surface of the light reflecting mirror from the blower, and the deposits removed from the surface of the reflecting mirror by the blow are collected by the dust collector.

7). A solar power generation reflector cleaning device for cleaning a light reflecting mirror provided in a solar thermal power generation system,
While moving at least one of the blower and the dust collector on the light reflecting mirror surface,
The dust collected by the dust collector is collected from the surface of the light reflecting mirror that is blown by a wind within a range of wind speed of 5 to 80 m / s from the blowing device toward the reflecting mirror surface. A cleaning device for a solar power generation reflector.

By the above means of the present invention, instead of using cleaning water to clean the light reflecting mirror that reflects sunlight, the surface of the light reflecting mirror is not damaged and the reflectance of the light to be collected is reduced. A cleaning method, a cleaning system, a solar power generation system, and a cleaning device for a solar power generation reflecting device that can perform less cleaning can be provided.
In other words, it is possible to clean the light reflecting mirror surface of the solar heat reflecting device with a gas such as wind without using cleaning water, and not only to clean the mirror surface but also to prevent the reattachment of dirt. And a reduction in reflectance can be suppressed.
The light reflecting mirror surface according to the present invention receives light from the surface layer 1 side as shown in FIG. 1, is reflected by the light reflecting layer 4, and the reflected light is emitted from the surface layer 1.

Hereinafter, the function and effect of the present invention will be described in more detail.
The light reflecting mirror (hereinafter also referred to as “sunlight reflecting mirror” or “reflecting mirror”) provided in the solar power generation reflecting device has a water contact angle of 80 to 170 °. An air blower and a dust collector are installed in the vicinity of the light reflecting mirror, and at least one of the air blower and the dust collector is moved on the surface of the mirror while moving from the air blower to the surface of the light reflecting mirror. The dust collected by the dust collecting device that blows in the air and collects the deposits removed by the blowing can not only clean the surface of the light reflecting mirror without scratching it, but also prevent reattachment of dirt. .
On the other hand, if the surface layer of the light reflecting mirror is a hydrophilic surface, the contact area of the adhered dirt is large and the reflectance is greatly reduced. Further, if the wind speed is simply increased to remove dirt, there is a concern that an object blown by the wind will collide with the mirror and cause damage to the mirror. In particular, the disadvantage of the trough-type light reflecting mirror made of glass is that a load is applied to make a curved surface.
However, by providing a layer with a water contact angle of 80 ° to 170 ° on the outermost surface of the light reflecting mirror of the solar power generation reflecting device, not only prevents the spread of dirt including condensation to the light reflecting mirror, Improves the efficiency of air blowing, reduces the amount of charge on the surface without the need for excessive air volume, and in a harsh environment such as a desert, by providing a dust collector as in the present invention, By collecting the dust before rising to the sky, it is possible to prevent the reattachment of dirt.

Sectional drawing which shows an example of the glass-made light reflection mirror layer structure used for the solar power generation reflective apparatus which concerns on this invention Sectional drawing which shows an example of resin-made light reflection mirror layer structure used for the solar power generation reflective apparatus which concerns on this invention Explanatory drawing which shows the solar thermal power generation system showing the condensing heat collection part used for the solar power generation reflective apparatus based on this invention, a heat transfer system, a thermal storage / heat exchanger, and a power generation part. Sectional drawing which shows an example of the air blower installed in the reflective mirror vicinity for solar power generation concerning this invention Sectional drawing which shows an example of the air blower installed in the reflective mirror vicinity for solar power generation concerning this invention Sectional drawing which shows an example of the dust collector installed in the reflection mirror vicinity for solar power generation concerning this invention Schematic showing the initial arrangement of the air blower and dust collector installed in the vicinity of the solar power generation reflective mirror according to the present invention Schematic which shows the time of cleaning of the air blower installed in the reflective mirror vicinity for solar thermal power generation concerning this invention, and a dust collector Schematic which shows the solar power generation reflective apparatus before installing a ventilation apparatus and a dust collector from the assistance vehicle which concerns on this invention.

The method for cleaning a solar power generation reflecting device of the present invention is a method of cleaning a solar power generation reflecting device including a light reflecting mirror that reflects sunlight having a surface layer having a water contact angle in the range of 80 to 170 °. A cleaning method for a solar power generation reflecting device to be cleaned, comprising: a blower device and a dust collector in the vicinity of the light reflecting mirror, and at least one of the blower device and the dust collector on the surface of the light reflecting mirror The dust collected from the surface of the light reflecting mirror by the air blowing is collected by the dust collecting device.
This feature is a technical feature common to or corresponding to the inventions according to claims 1 to 7.
As an embodiment of the present invention, it is preferable from the viewpoint of the effect of the present invention that the light reflecting mirror is an embodiment having a light reflecting layer on a resin base material. Further, the device that moves on the light reflecting mirror is the air blower and the dust collecting device, and at least one device that moves on the light reflecting mirror has a static eliminator, and neutralizes the surface of the reflective mirror. It is preferable to move while improving the cleaning efficiency. Furthermore, it is preferable from the same viewpoint that the wind speed of the air discharged from the blower is 5 to 80 m / s.

  The solar power generation reflecting device cleaning system of the present invention is a solar power generation reflecting device cleaning system that cleans the light reflecting mirror for reflecting sunlight provided in the solar power generating reflecting device with gas, The reflection mirror has a surface layer having a water contact angle in the range of 80 to 170 °, and includes a blower and a dust collector near the light reflection mirror, and at least the blower on the surface of the light reflection mirror And while moving either one of the dust collectors, the dust collected by the dust collector is blown from the blower device toward the surface of the light reflecting mirror, and removed from the surface of the light reflecting mirror by blowing. It is characterized by collecting dust.

  The solar thermal power generation system of the present invention is a solar thermal power generation system having a plurality of light reflecting mirrors that reflect sunlight and a cleaning device that cleans the surface of the light reflecting mirror, wherein the cleaning device includes the reflecting mirror. The water contact angle of the surface is in the range of 80 to 170 °, and has a blower and a dust collector for installation in the vicinity of the reflection mirror surface, and at least the blower on the light reflection mirror surface, While moving either one of the dust collectors, air is blown from the blower toward the surface of the light reflecting mirror, and the deposits removed from the surface of the reflecting mirror by blowing are collected by the dust collector. It is characterized by.

  The solar power generation reflecting device cleaning device according to the present invention is a solar power generation reflecting device cleaning device for cleaning a light reflecting mirror, which is provided in a solar power generation system, and at least the air blowing on the surface of the light reflecting mirror. While moving either one of the apparatus and the dust collector, the air in the range of 5 to 80 m / s is blown from the blowing device toward the reflecting mirror surface, and the light reflecting mirror surface is blown by the blowing. The deposits removed from the dust are collected by the dust collector.

Hereinafter, the present invention, its components, and modes and modes for carrying out the present invention will be described in detail. In addition, "-" shown in this invention is used in the meaning which includes the numerical value described before and behind that as a lower limit and an upper limit.
《Reflection mirror》
The light reflecting mirror used in the present invention is a light reflecting mirror using glass as a base material (hereinafter referred to as (A) glass reflecting mirror), or a reflecting mirror using resin as a base material (hereinafter referred to as (B). ) (Referred to as a resin reflecting mirror).
The (A) glass reflection mirror according to the present invention is a light reflection mirror having at least a surface layer, a glass substrate, and a light reflection layer from the light incident side as constituent layers.
Further, another constituent layer may be provided on each constituent layer, or the constituent layers may be adjacent to each other.
As an example of a glass reflecting mirror configuration according to the present invention, as shown in FIG. 1, a surface layer 1 is provided by being laminated on a flat glass substrate 3A. A light reflection layer 4 and a corrosion prevention layer 5 are provided on the other side of the flat glass substrate 3A.

Next, the (B) resin reflection mirror configuration according to the present invention includes (i) a reflection mirror having a surface layer, a light reflection layer, and a resin base material in order from the light incident side, or (ii) the light incident side. It is preferable that it is a reflective mirror of the structure which has a surface layer, a resin base material, and a light reflection layer in order.
Regarding the configuration of (i), the light reflecting layer is preferably located on the light incident side from the resin base material, which is preferable from the viewpoint of suppressing deterioration of the resin base material due to long-term exposure. It is preferable from the viewpoint of suppressing cracks in the surface layer due to curing shrinkage and ensuring adhesion, when the substrate is located on the light incident side from the light reflecting layer.
Further, another constituent layer may be provided between the constituent layers described above or on the constituent layer, or the respective layers may be adjacent to each other.
For example, an anchor layer may be provided between the resin base material and the light reflecting layer, or a corrosion prevention layer may be provided adjacent to the opposite side of the light reflecting side of the light reflecting layer. Further, a gas barrier layer and / or a translucent resin layer may be provided on the light incident side or the opposite side of the light reflecting layer.
And although the thickness of the entire reflecting mirror according to the present invention is not particularly limited, it is preferably 80 to 300 μm when using a resin film for the base material from the viewpoints of prevention of bending, good regular reflectance, handling properties, etc. More preferably, it is 80-200 micrometers, More preferably, it is 80-170 micrometers.

  As an example of the resin reflecting mirror configuration according to the present invention, as shown in FIG. 2, a translucent resin layer 2 and a surface layer 1 are sequentially laminated on a resin base material 3 </ b> B, opposite to the light incident side. A light reflecting layer 4, a corrosion preventing layer 5, and an adhesive layer 6 are provided.

Details of each constituent layer will be described below.
(Surface layer)
In the present invention, the water contact angle on the mirror surface of the present invention may be adjusted by any method, but it is easy to adjust the water contact angle by providing a surface layer in terms of design. The surface layer 1 according to the present invention is a layer having a water contact angle of 80 to 170 °, and the configuration makes it possible to narrow the contact area of the adhered dirt and suppress a decrease in reflectance. If the water contact angle of the surface layer is 80 ° or more, it is possible to suppress the spread of dirt including condensation on the reflection mirror, and if the water contact angle is 170 ° or less, the surface of the reflection mirror is cleaned without being scratched. Can be done. The water contact angle is desirably 100 to 150 °.
A well-known method can be adopted to set the water contact angle within the range. For example, the polysiloxane coating solution represented by the general formula (1) described in paragraphs 0026 to 0044 of International Publication No. 2011/96309 may be applied to form a polysiloxane layer, or the polysiloxane layer may be further added to the polysiloxane layer. You may make it laminate | stack using the coating liquid containing the said surface treating agent.

式中、Ｒ^１１、Ｒ^１２は同一であっても異なっていてもよく、水素原子又はアルキル基
若しくはアリール基等の有機基を表す。
前記表面処理剤としては、ポリアルキルアクリレート等のポリアクリレート系ポリマー；ポリアルキルビニルエーテル等のポリビニルエーテル系ポリマー；ジメチルポリシロキサン、メチルフェニルポリシロキサン、さらにはポリエーテル、ポリエステル、アラルキル等が導入された有機変性ポリシロキサン等のシリコーン系ポリマー等が例示される。

In the formula, R ¹¹ and R ¹² may be the same or different and each represents a hydrogen atom or an organic group such as an alkyl group or an aryl group.
Examples of the surface treatment agent include polyacrylate polymers such as polyalkyl acrylates; polyvinyl ether polymers such as polyalkyl vinyl ethers; dimethylpolysiloxanes, methylphenylpolysiloxanes, and organics including polyethers, polyesters, aralkyls, and the like. Examples thereof include silicone polymers such as modified polysiloxane.

Leveling agents that can be used in the present invention are those containing fluorine atoms in these polymers. A leveling agent having a fluorine atom can be obtained, for example, by copolymerizing a monomer having a fluorine-containing group.
As the surface treatment agent, for example, Surflon “S-381”, “S-382”, “SC-101”, “SC-102”, “SC-103”, “SC-104” (all manufactured by Asahi Glass Co., Ltd.) ), FLORARD "FC-430", "FC-431", "FC-173" (all made by Fluorochemicals-Sumitomo 3M), F-top "EF352", "EF301", "EF303" (all Shin-Akita Kasei) Co., Ltd.), Schwego Fureer "8035", "8036" (both made by Schwegman), "BM1000", "BM1100" (both made by BM Himmy), MegaFuck "F-171", " F-470 "," RS-75 "," RS-72-K "(manufactured by DIC Corporation), BYK340 (manufactured by Big Chemie Japan)," ZX-0 " 9 "," ZX-001 "," ZX-017 "(manufactured by both Fuji Chemical Industry Co., Ltd.), etc. Beatiful G'ZOX real glass coating (software made by 99 companies) are commercially available.

On the other hand, since the surface treatment layer 1 is a layer having a water contact angle of 80 to 170 °, the inorganic crystal layer having at least a fine concavo-convex structure and fluorine described in paragraphs 0044 to 0099 of JP2013-245849A It is good also as a coat layer.
The contact angle of water according to the present invention can be measured by dropping 3 μl of water droplets onto a reflection mirror in an environment of 23 ° C. and 55% RH using a contact angle CA-W manufactured by Kyowa Interface Science.

(Translucent resin layer)
The translucent resin layer 2 is preferably a translucent resin layer containing an ultraviolet absorber. The translucent resin layer is preferably provided by coating because it is not necessary to bond the layers through an adhesive layer, and air bubbles and foreign substances are not mixed between the layers, and a decrease in light reflectivity can be prevented.
The translucent resin layer is preferably provided on the light incident side of the resin base material, and is preferably provided between the resin base material and the surface layer.
Although there is no restriction | limiting in particular in the resin material used for the translucent resin layer 2, Various conventionally well-known synthetic resins which can maintain transparency when forming a thin film can be used. For example, polyesters such as polyethylene terephthalate and polyethylene naphthalate, polyethylene esters, polyethylene, polypropylene, cellophane, cellulose diacetate, cellulose triacetate, cellulose acetate butyrate, cellulose acetate propionate, cellulose esters such as cellulose acetate phthalate and cellulose nitrate or the like Derivatives, polyvinylidene chloride, polyvinyl alcohol, polyethylene vinyl alcohol, syndiotactic polystyrene, polycarbonate, norbornene resin, polymethylpentene, polyetherketone, polyimide, polyethersulfone, polysulfones, polyetherketoneimide, polyamide, fluororesin Nylon, polymethyl methacrylate, acrylic or Polyarylates, and cycloolefin resins such as ARTON (trade name JSR Corp.) or APEL (trade name Mitsui Chemicals, Inc.).
Examples of a method for forming the translucent resin layer 2 include a method by coating. When a coating film that becomes the translucent resin layer 2 is applied by a coating method, various conventionally used coating methods such as spray coating, spin coating, and bar coating can be used.

Although there is no restriction | limiting in particular in the ultraviolet absorber contained in the translucent resin layer 2, For example, organic ultraviolet absorbers, such as a thiazolidone type, a benzotriazole type, an acrylonitrile type, a benzophenone type, an aminobutadiene type, a triazine type, Alternatively, there are fine powder type ultraviolet blocking agents such as cerium oxide and magnesium oxide, and organic ultraviolet absorbers are particularly preferable.
As organic ultraviolet absorbers, for example, JP-A-46-3335, JP-A-55-152776, JP-A-5-197704, JP-A-5-232630, JP-A-5-307232, JP-A-6-218131, and 8- No. 53427, No. 8-234364, No. 8-239368, No. 9-31067, No. 10-115898, No. 10-147777, No. 10-182621, German Patent No. 19739797A, European Patent No. 711804A and JP-A-8-501291, U.S. Pat. Nos. 1,023,859, 2,685,512, 2,739,888, 2,784,087. No. 2,748,021, No. 3,004,896, No. 3,052,636, No. 3,215,530, No. 3,253,92 No. 3,533,794, No. 3,692,525, No. 3,705,805, No. 3,707,375, No. 3,738,837, No. 3 , 754,919, British Patent 1,321,355 and the like.

(Base material)
As the substrate, a conventionally known glass substrate or resin substrate can be used. As the resin substrate, there are resin plates and resin films, and if a reflection mirror is formed on the resin plate, a reflection mirror device can be produced without using a support substrate like a glass substrate, and a reflection mirror is formed on the resin film. If formed, it is possible to obtain a flexible reflection mirror that can be mass-produced and can match the shape of the installation place and the shape of the mirror. In the present invention, a resin reflection mirror is preferable.
The thickness of the resin base material is not particularly limited, but is preferably an appropriate thickness depending on the type and purpose of the resin. As for the thickness of a glass substrate and a resin board, 1-10 mm is preferable, for example, More preferably, it is 2-5 mm. The thickness of the resin film is preferably in the range of 10 to 250 μm, for example, and more preferably 20 to 200 μm.

  As a resin base material, conventionally well-known various following resin films can be used. For example, cellulose ester film, polyester film, polycarbonate film, polyarylate film, polysulfone (including polyethersulfone) film, polyethylene terephthalate film, polyester film such as polyethylene naphthalate, polyethylene film, polypropylene Film, cellophane film, cellulose diacetate film, cellulose triacetate film, cellulose acetate propionate film, cellulose acetate butyrate film, polyvinylidene chloride film, polyvinyl alcohol film, ethylene vinyl alcohol film, Syndiotactic polystyrene film, polycarbonate film, norvo Examples of the film include a ene film, a polymethylpentene film, a polyether ketone film, a polyether ketone imide film, a polyamide film, a fluorine film, a nylon film, a polymethyl methacrylate film, and an acrylic film. . Among these, polycarbonate films, polyester films such as polyethylene terephthalate, norbornene resin films, cellulose ester films, and acrylic films are preferable. Of these, a polyester film such as polyethylene terephthalate or an acrylic film is preferably used, and a polyester film such as polyethylene terephthalate is particularly preferable. Here, the resin substrate may be manufactured by any method, for example, a substrate manufactured by melt casting film formation, or a substrate manufactured by solution casting film formation. May be.

(Light reflecting layer)
The light reflecting layer 4 is a layer having a function of reflecting light. In particular, a layer made of metal or the like is preferable. The surface reflectance of the light reflection layer is preferably 80% or more, more preferably 90% or more. This light reflecting layer is preferably formed of a material containing any element selected from the group consisting of Al, Ag, Cr, Cu, Ni, Ti, Mg, Rh, Pt and Au. Among these, it is preferable that Al or Ag is a main component from the viewpoint of reflectance and corrosion resistance, and two or more such metal thin films may be formed. In the present invention, a light reflecting layer mainly containing silver is particularly preferable.
The thickness of the light reflecting layer is preferably in the range of 10 to 200 nm, more preferably in the range of 30 to 150 nm, from the viewpoint of reflectance and the like.
In addition, a layer made of a metal oxide such as SiO ₂ or TiO ₂ may be provided on the incident side in the light reflecting layer to further improve the reflectance.
As a method for forming the light reflecting layer, either a wet method or a dry method can be used. The wet method is a general term for a plating method, and is a method of forming a film by depositing a metal from a solution. Specific examples include silver mirror reaction.
On the other hand, the dry method is a general term for a vacuum film-forming method. Specific examples include a resistance heating vacuum deposition method, an electron beam heating vacuum deposition method, an ion plating method, and an ion beam assisted vacuum deposition method. And sputtering method. In particular, a vapor deposition method capable of a roll-to-roll method for continuously forming a film is preferably used in the present invention. For example, in the manufacturing method of the reflective mirror for solar thermal power generation, it is preferable that the light reflecting layer is formed by silver deposition (particularly vacuum deposition).

(Corrosion prevention layer)
The corrosion prevention layer is a resin layer containing a corrosion inhibitor and is preferably adjacent to the light reflection layer.
The corrosion prevention layer may consist of only one layer or may consist of a plurality of layers.
The thickness of the corrosion prevention layer is preferably 1 to 10 μm, more preferably 2 to 8 μm.
The resin and corrosion inhibitor used in the corrosion prevention layer are not particularly limited, but are described in known literatures such as WO 2012/165460 pamphlet (particularly, paragraphs “0079” to “0095”). Similar materials can be used.
The corrosion inhibitor preferably has an adsorptive group for silver. Here, “corrosion” refers to a phenomenon in which a metal (silver) is chemically or electrochemically eroded or deteriorated by an environmental material surrounding it (see JIS Z0103-2004).
The optimum content of the corrosion inhibitor varies depending on the compound used, but is generally preferably in the range of 0.1 to 1.0 g / m ² .

(Adhesive layer)
The adhesive layer 6 has an adhesive property that allows the resin reflecting mirror to be attached to the supporting base material, and the adhesive reflecting layer is joined to the supporting base material by this adhesive layer to reflect solar power generation. It is a layer for forming a device.
The adhesive layer is not particularly limited, and for example, any of a dry laminating agent, a wet laminating agent, an adhesive, a heat seal agent, a hot melt agent, and the like is used. As the adhesive, for example, a polyester resin, a urethane resin, a polyvinyl acetate resin, an acrylic resin, a nitrile rubber, or the like is used. The laminating method is not particularly limited, and for example, it is preferable to carry out the roll method continuously from the viewpoint of economy and productivity.
Moreover, it is preferable that the thickness of an adhesion layer is the range of about 1-100 micrometers normally from viewpoints, such as an adhesion effect and a drying rate.
The resin reflecting mirror may include a release sheet (not shown) that covers the surface of the adhesive layer opposite to the resin base material. When the resin reflection mirror has a release sheet, the resin reflection mirror can be attached to the support substrate via the adhesive layer after the release sheet is released from the adhesive layer.

Hereinafter, functional layers other than the above constituent layers will be described.
(Gas barrier layer)
The gas barrier layer is preferably provided on the light incident side with respect to the light reflecting layer. In particular, it is preferable to provide a gas barrier layer between the resin substrate and the light reflecting layer.
The gas barrier layer is intended to prevent the deterioration of humidity, especially the deterioration of the resin base material and each component layer supported by the resin base material due to high humidity, but with special functions and applications. As long as it has a function of preventing deterioration, a gas barrier layer of various modes can be provided. As the moisture resistance of the gas barrier layer, the water vapor permeability at 40 ° C. and 90% RH is preferably 1 g / m ² · day or less, more preferably 0.5 g / m ² · day or less, still more preferably It is 0.2 g / m ² · day or less. In addition, the oxygen permeability of the gas barrier layer is preferably 0.6 ml / m ² · day · atm or less under the conditions of a measurement temperature of 23 ° C. and a humidity of 90% RH.
The material used for the gas barrier layer and the method for forming the gas barrier layer are not particularly limited. For example, it is disclosed in known documents such as WO 2012/165460 pamphlet (particularly, paragraphs “0188” to “0209”). Similar materials and methods as described can be used.

(Anchor layer)
The anchor layer can be disposed between the resin substrate and the light reflecting layer. The anchor layer is made of a resin material and adheres the resin base material and the light reflection layer. Therefore, the anchor layer has an adhesion property that allows the resin base material and the light reflection layer to adhere to each other, heat resistance that can withstand heat when the light reflection layer is formed by a vacuum deposition method, and the high reflection that the light reflection layer originally has. Smoothness is required to bring out performance.
The material (resin material) used for the anchor layer and the method for forming the anchor layer are not particularly limited. For example, publicly known publications such as WO 2012/165460 (particularly, paragraphs “0209” to “0212”) are known. Materials and methods similar to those described in the literature can be used.

<Reflector for solar power generation>
If the resin base material is a resin film, the solar power generation reflection device has a reflection mirror and a self-supporting support base material, and the reflection mirror is bonded to the support base material through an adhesive layer. It is a mirror. Further, if the resin base material is a resin plate or a glass base material, a support base material may be used as appropriate.
In addition, the "self-supporting property" as used herein means that the support base material supports the edge portion of the reflection mirror in a state where the support base material is cut into a size used as a support base material for a solar power generation reflection device. This means that the reflector has rigidity enough to support the reflecting mirror. The support base material of the solar power generation reflecting device has self-supporting properties, so that it is easy to handle when installing the solar power generation reflecting device, and the holding member for holding the solar power generation reflecting device has a simple configuration. Therefore, it is possible to reduce the weight of the reflection device itself, and it is possible to suppress power consumption during solar tracking.

(Supporting substrate)
As a self-supporting support base material, there are one having a pair of metal flat plates and an intermediate layer interposed between the metal flat plates (type A), or one made of a resin material having a hollow structure (type B). It is preferable. About a specific structure, the self-supporting base materials A and B described in the international publication 11/162154 pamphlet or US Patent application publication 2013/0114155 etc. are employable.
For example, as shown in FIG. 2, the solar power generation reflecting device 20 </ b> B can be formed by being attached to the support substrate 7 via the adhesive layer 6.
Moreover, the glass light reflecting mirror 10A can form the reflecting device 20A for solar power generation by press-molding and bending a flat white glass mirror with a heated mold.

<Reflector unit for solar power generation>
(Holding member)
As shown in FIG. 3, the solar power generation reflector unit 22B includes a holding member 21 that holds the reflector itself.
It is preferable that the holding member holds the reflecting mirror in the solar power generation reflecting device in a state where the sun can be tracked. The form of the holding member is not particularly limited, but for example, a plurality of places on the support base on the back side of the solar power generation reflecting device are formed in a bar shape so that the solar power generating reflection device can hold a desired shape and posture. The form held by a columnar member or a beam-like member is preferable.
The holding member has a configuration for holding the solar power generation reflecting device in a state in which the sun can be tracked. However, in the case of solar tracking, the holding member may be driven manually, or a separate driving device may be provided to automatically track the sun. It is good also as composition to do.

《Solar thermal power generation system》
Next, a solar power generation system using 22B, which is an example of a solar power generation reflector unit, will be described. FIG. 3 is an explanatory view of the solar thermal power generation system as viewed from the side.
Here, a trough solar thermal power generation system will be described as an example, but a tower top solar thermal power generation system or a beam down solar thermal power generation system may be used.
In the trough-type solar power generation device 30 as shown in FIG. 3, for example, the solar power generation reflection device unit 22 </ b> B includes a holding member 21 planted on the ground and a solar power generation reflection device attached to the upper end of the holding member 21. 20B. The holding member 21 can be tracked by the sun, and the elevation angle of the holding member 21 can be changed with respect to the holding member 21 by an actuator. The solar power generation reflecting device 20B always reflects sunlight toward the heat collecting tube 31. It is like that.
For example, a heat collection tube 31 is installed at the light collection position on the front surface of the solar power generation reflector 20B. A heat medium such as water, molten salt, or oil flows through the heat collection pipe 31 and is heated by sunlight collected by the solar power generation reflection device 20B, while the heat collection pipe 31 has a heat exchange facility 33 through the transport pipe 32. Power is generated by being sent to a steam turbine to evaporate water and turning the steam turbine.

《Cleaning solar power reflectors》
Next, a method for cleaning the reflection mirror surface of the solar power generation reflector unit 22B used in the solar thermal power generation system will be described.
As described above, the solar power generation reflector unit is provided on the desert ground, and the solar power generation reflector unit of the solar power generation reflector unit exposed to the outdoor environment has dust dirt attached thereto. Therefore, in order to maintain the reflectance of the solar power generation reflecting device well, it is necessary to appropriately clean the reflection mirror surface of the solar power generation reflecting device.

(Blower)
Hereinafter, the blower according to the present invention will be described with reference to the drawings.
4 and 5 show a configuration of a blower installed in a solar power generation reflecting device according to an embodiment of the present invention.
As shown in FIG. 4, the blowing device 40 on the reflecting mirror has a moving function for moving on the reflecting mirror, for example, a wheel, or a device by which the blowing device can be moved by towing. Can be used. The air blower 40 blows air toward the reflecting mirror and blows air while reciprocating the reflecting mirror. Even if the air blower moves continuously, it may stop at places where there are many deposits, and air may be blown intermittently.
The blower device 40 has a wind direction adjusting member 41 so that the optimum air volume and the angle of the wind to the deposit can be adjusted according to the adhesion state of the deposit on the reflection mirror, the shape of the reflection mirror, and the like. Composed. The wind direction adjusting member 41 may have a function of automatically adjusting the angle (θ °) formed by a string with respect to the arc of the reflection mirror and an extension line of the wind direction adjusting member 41 to be 45 ° or less.
The wind speed of the gas discharged from the blower 40 is 5 to 80 m / s. The wind speed for removing the deposits is preferably within the above range, and if it is 5 m / s or more, the deposits are unlikely to rise, and a decrease in reflectance due to reattachment can be suppressed. The surface is less likely to be scratched, and charging after blowing can be suppressed.
In addition, the wind speed in this invention measured the gas discharged | emitted from an air blower by installing the wind speed measuring device (Anemo master anemometer Model 6141, Nippon Kanomax Co., Ltd.) from the position of the wind direction adjustment member.

Moreover, the air blower 40 may have the several wind direction adjustment member 41, as shown in FIG. When the blower device has a plurality of wind direction adjusting members 41a and 41b, it is preferable to discharge gases having different wind speeds, and the wind speed discharged from the blower opening located farthest from the reflecting mirror is changed to the blower opening at the lower part. In some cases, it is possible to further suppress the reattachment of dirt by making the speed higher than the wind speed discharged from the air. Further, the same effect can be obtained by providing a wind direction adjusting member near both ends and making the wind speed discharged from both ends larger than the wind speed discharged from the inside.
In addition, as shown in FIG. 8, the blower may be cleaned while moving in the vertical direction as indicated by an arrow, whereas the blower and the dust collector may be cleaned while moving in the horizontal direction.
Examples of the gas discharged from the blower 40 include an inert gas (for example, nitrogen, carbon dioxide, argon), oxygen, air, and the like, and preferably air (including wind). Further, from the viewpoint of preventing condensation, it may be dry air or ionized air.

In addition, as shown in FIG. 5, the blower 40 that moves on the reflection mirror may have a static eliminator 42. The static eliminator 42 may eliminate static electricity while the air blower moves while blowing air, or may remove static electricity when moving the air blower device to a predetermined position after the air blow ends. Preferably, the static electricity is removed downstream in the blowing direction during blowing. Thereby, it becomes possible to suppress the reattachment of dirt on the reflecting mirror surface.
The static eliminator 42 may be any one of an ionizer, a soft X-ray irradiator, an ultraviolet irradiator, and a static eliminator brush, preferably a static eliminator brush. In addition, the static elimination brush said here is a self-discharge type brush formed with the grounded conductive fiber. When the static eliminator is installed, after the cleaning, the device having the static eliminator moves at least once from the end to the end on the solar power generation reflecting device 20B and performs static elimination.

(Dust collector)
The dust collector according to the present invention will be described below with reference to the drawings.
FIG. 6 shows a configuration of a dust collector 50 installed in a solar power generation reflecting device according to an embodiment of the present invention.
As shown in FIG. 6, the dust collector 50 has a gripping member 52, is gripped by the end of the solar power generation reflecting device 20, and is dusted off by the air blower of the blower at the dust collection portion 51. But before it soars, it collects dust. Therefore, it is preferable that the dust collector has at least a dust collecting function downstream in the blowing direction of the blower. The dust collection in the present invention only needs to collect dust on the light reflection mirror, and the dust collection means may be only a filter for separating and collecting dirt, or a suction device. This is preferable from the viewpoint of reducing the frequency of filter maintenance. As in the case of the blower, the dust collector may have a moving device, and may collect dust while moving on the reflecting mirror.

(Cleaning method)
Next, a specific method for removing dirt on the reflecting mirror surface of the solar power generation reflecting device 20B according to one embodiment of the present invention will be described with reference to FIGS.
In the solar thermal power generation system as shown in FIG. 3, it is necessary to clean a vast number of solar thermal power generation reflectors provided on a vast site in the desert. As shown in FIG. 7, a blower 40 and a dust collector 41 are installed in the vicinity of the solar power generation reflection device 20B for each solar power generation reflection device unit 22B. Next, as shown in FIG. 8, the blower 40 blows gas to the reflection mirror while the blower 40 continuously or intermittently reciprocates from end to end on the reflection mirror 10, and While the dust collector 50 collects dust, the dirt on the reflecting mirror surface of the solar power generation reflecting device 20B is removed.
It should be noted that at least one of the blowing device and the dust collecting device installed on the light reflecting mirror may be cleaned while moving, but it suppresses charging on the reflecting mirror and reattachment due to the rising of the deposit by blowing. Therefore, it is preferable that both the blower and the dust collector are cleaned while moving. For the purpose of improving dust collection efficiency, it is preferable to perform blowing and dust collection by moving the blower and the dust collector while maintaining a certain distance. From such a viewpoint, although the air blower and the dust collector have been described separately, an apparatus having an integral structure may be used.
Further, when the solar power generation reflector unit 22 is automatically cleaned, for example, a self-propelled robot system described in paragraphs 0034 to 0050 of JP 2010-155308 A may be introduced.
As a self-propelled robot system, the support vehicle 60 is automatically driven unattended and installed at an initial position as shown in FIG. 9, and after the cleaning is completed, the blower 40 and the dust collector 50 are placed on the solar power generation reflector 20B. The system which collect | recovers and repeats transfer to the solar power generation reflective apparatus 20B of the solar power generation reflective apparatus unit 22B which adjoins is mentioned. Further, the support vehicle 60 may have a mechanism for collecting the collected dust collector.
When the solar power generation reflective device is automatically cleaned, the environmental change is observed, and the predetermined condition is, for example, when the relative humidity on the reflection mirror is 60% or more, or due to adhesion of dust or the like, the reflectance becomes 80% or less. The cleaning system may be activated at the time, or the cleaning system by the self-propelled robot system may be operated for a predetermined period, for example, once every two weeks.

EXAMPLES Hereinafter, the present invention will be specifically described with reference to examples, but the present invention is not limited thereto. In addition, although the display of "%" is used in an Example, unless otherwise indicated, "mass%" is represented.
[Production of reflector for solar power generation]
(Reflector for solar thermal power generation [1])
A flat white plate glass 3A having a width of 1.5 m, a length of 2 m, and a thickness of 3 mm was used as a glass substrate, and electroless silver plating was performed on one side to form a light reflecting layer 4. On the light reflection layer 4, a polyester resin (Polyester SP-181, manufactured by Nippon Synthetic Chemical Industry Co., Ltd.) and a TDI isocyanate (2,4-tolylene diisocyanate, manufactured by Tokyo Chemical Industry Co., Ltd.) as a curing agent. An amount adjusted to 0.3 g / m ² after applying glycol dimercaptoacetate as a corrosion inhibitor is added to the resin mixed at a resin solid content ratio of 10: 2, and the film thickness is increased by gravure coating. The first corrosion prevention layer was coated to a thickness of 0.1 μm. Furthermore, a water-dispersed emulsion type benzotriazole-based polymer type UV-absorbing coating solution UVA-1383MG (manufactured by BASF Japan Ltd.) is coated thereon by a gravure coating method, dried at 55 ° C. for 4 minutes and a thickness of 3 μm. A second corrosion protection layer was formed. Here, the first and second corrosion prevention layers were combined to form a corrosion prevention layer 5.
A surface layer forming liquid A was prepared by diluting a metalloxane-based silicone liquid (BP-16N solid content 40%, manufactured by Doken Co., Ltd.) with methyl ethyl ketone (MEK) to a concentration of 30% by mass. This surface layer forming liquid is applied to the other glass surface opposite to the surface on which the corrosion prevention layer 5 is formed so as to have a thickness (dry film thickness) of 3 μm by gravure coating. The surface layer 1 was formed on the glass surface by drying / curing for a minute, and the flat plate glass mirror was produced. In order to obtain a trough shape, a flat white plate glass mirror was press-molded and bent with a mold heated to 300 ° C. to produce a solar power generation reflector [1].

(Reflector for solar thermal power generation [2])
A biaxially stretched polyethylene terephthalate film having a thickness of 50 μm was used as the resin substrate. On the one surface of the film, as the light reflecting layer 4, a silver light reflecting layer 4 having a thickness of 80 nm was vacuum-deposited at a deposition speed of 100 m / sec by a vacuum deposition method. On the light reflection layer 4, the same corrosion prevention layer 5 as the solar power generation reflection device [1] was formed.
PMMA resin (EMB457, manufactured by Mitsubishi Rayon Co., Ltd.), acrylic rubber (SRB215, manufactured by Asahi Kasei Chemicals Co., Ltd.), triazine UV absorber (Tinuvin 479, manufactured by BASF Japan Ltd.), benzotriazole UV absorber (Tinuvin 928, BASF Japan) Co., Ltd.) is mixed in methyl ethyl ketone (MEK) so that the mixing ratio is 17: 3: 0.68: 0.43 (solid content ratio) and the solid content concentration is 21% by mass. A light resin layer forming solution was prepared.
This translucent resin layer forming liquid is applied to the surface of the other resin film opposite to the surface on which the corrosion prevention layer 5 of the polyethylene terephthalate film is formed, with a bar coater so that the thickness (dry film thickness) is 25 μm. Then, the transparent resin layer 2 having a thickness of 25 μm was formed by drying at 80 ° C. for 1 minute. The surface layer 1 similar to the solar power generation reflection device [1] was formed on the translucent resin layer 2 to produce a resin reflection mirror.
An acrylic adhesive (Nissetsu SZ-7103, manufactured by Nippon Carbide Industries Co., Ltd.) was dried and laminated with a release film coated to a thickness of 25 μm on the surface of the corrosion-preventing layer 5 of the resin reflective mirror. An adhesive layer 6 was formed. A reflective mirror made of resin was attached to an aluminum plate having a width of 1.5 m, a length of 2 m, and a thickness of 1 mm via an adhesive layer, thereby producing a solar power generation reflecting device [2].

(Reflector for solar thermal power generation [3])
The surface layer forming liquid A used in the production of the solar power generation reflecting device [1] is applied on the translucent resin layer 2 by gravure coating so that the thickness (dry film thickness) becomes 3 μm. A solar power generation reflection device [3] was produced in the same manner as the solar power generation reflection device [2] except that the surface layer 1 was formed by drying / curing at ° C for 2 minutes.

(Reflector for solar thermal power generation [4])
Instead of the surface layer 1 used in the solar power generation reflection device [2], a 3% perhydropolysilazane liquid (NL120, manufactured by AZ Electric Materials Co., Ltd.) in dibutyl ether is used on the translucent resin layer 2. Bar coating was performed so that the thickness of the dried film was 500 nm, air drying was performed for 3 minutes, and then a layer was formed by drying / curing for 30 minutes in an oven at 90 ° C. Further, a surface treatment agent for a silicone-based polymer ( A solar thermal power generation reflector [4] was prepared in the same manner as the solar power generator reflector [2], except that the surface layer 1 was obtained by bar coating with Soft 99 Beatiful G'ZOX Real Glass Coat).

(Reflector for solar power generation [5])
After drying on the translucent resin layer 2 using 3% perhydropolysilazane liquid (NL120 manufactured by AZ Electric Materials) in dibutyl ether instead of the surface layer 1 used in the solar power generation reflector [2]. The film was bar-coated so that the thickness of the film became 500 nm, naturally dried for 3 minutes, and then dried / cured in an oven at 90 ° C. for 30 minutes to form a layer. As an inorganic compound for crystal formation, Ca (NO ₃ ) ₂ , KF, (NH ₄ ) ₂ HPO ₄ , and as a flux, LiNO ₃ and KNO ₃ were added in an amount of 5% by mass, and 10 ml of water was added. An inorganic compound solution for growing fluorapatite crystals was prepared.
Next, the inorganic compound solution was applied onto the layer with a bar coater at a wet film thickness of 100 nm, and then subjected to atmospheric pressure nitrogen plasma treatment to obtain an inorganic crystal layer having hexagonal columnar crystals. The plasma treatment was performed with an input power of 150 W, a nitrogen flow rate of 5.0 liters per minute, a space between the plasma torch and the substrate of 10 mm, and an irradiation time of 120 seconds. Next, a solution obtained by diluting Optool DSX (manufactured by Daikin Industries Co., Ltd.) 100 times with Novec 7000 (manufactured by 3M Corporation) as a fluorine coat layer on the inorganic crystal layer with a wet film thickness of 3 μm using a bar coater. The solar power generator reflector [5] is the same as the solar power generator reflector [2] except that the surface layer 1 is obtained by drying at 80 ° C. for 30 seconds, washing with ethanol, and drying to obtain the surface layer 1. Was made.

(Reflector for solar thermal power generation [6])
A solar power generation reflector [6] was produced in the same manner except that the surface layer 1 of the solar power generation reflector [1] was not provided.

(Reflector for solar thermal power generation [7])
A solar power generation reflector [7] was prepared in the same manner except that the surface layer 1 of the solar power generation reflector [2] was not provided.

(Reflector for solar thermal power generation [8])
Instead of the surface layer 1 used in the solar power generation reflector [2], an ethyl acetate solution of methyl acrylate / butyl acrylate copolymer (ratio 64:36) has a thickness (dry film thickness) of 3 μm by a gravure coating method. The solar power generation reflector [2] is the same as the solar power generation reflector [2] except that the surface layer 1 is prepared by irradiating with ultraviolet rays at 100 mJ / cm ² after drying at 80 ° C. for 4 minutes. 8] was produced.

[Cleaning method]
Table 1 shows the conditions of the cleaning method for the solar power generation reflector. The dust collector is located downstream of the blower, the number of wind direction adjusting members refers to the embodiment of the blower explained in FIG. 5, and the moving device name is a device that moves on the reflecting mirror by a wheel. “Intermittent” in the method means that the moving device pauses at an intermediate position on the reflecting mirror, blows or collects dust, and then cleans while moving again. Moreover, in the cleaning method J, the static elimination bar performed the static elimination work by moving on the reflection mirror once when the blower moved and after cleaning.

[Evaluation of reflectors for solar power generation]
(Water contact angle test)
Based on JIS-R3257, 3 μl of water was dropped on the surface of the reflecting mirror in an atmosphere of a temperature of 23 ° C. and a relative humidity of 55%, and a contact angle meter DM300 (Kyowa Interface Chemistry) ).

(Measurement of regular reflectance)
Using a spectrophotometer “U-4100” manufactured by Shimadzu Corporation, the regular reflectance at an incident angle of incident light of 5 ° was measured with respect to the normal line of the reflecting surface. Evaluation was measured as an average reflectance from 250 nm to 2500 nm.

(Steel wool test)
As a scratch resistance test, steel wool (# 0000) was attached as a wear material to a reciprocating wear tester (HEIDON-14DR manufactured by Shinto Kagaku Co., Ltd.), and the surface layer of the reflecting mirror was moved at a speed of 500 g / cm ^2. It was reciprocated 10 times at 10 mm / sec. The number of scratches at that time was measured and evaluated.

(Outdoor exposure test)
Using the solar power generation reflectors [1] to [8], cleaning samples shown in Table 2 below were prepared and installed in the desert of Saudi Arabia. After that, when the reflectance was greatly reduced due to dirt, the cleaning cycle shown in Table 1 was carried out for 3 months. After 3 months, it was cleaned again and the steel wool test and specular reflectance were measured.
Table 2 shows the evaluation results for each item.

表２からわかるように本発明に係る太陽熱発電用反射装置の清浄方法は比較例に対して優れていることが分かる。
比較例である試料Ｎｏ．１３は、送風装置のみで清浄するので送風後の舞い上がった付着物がミラー上に再付着してしまい、反射率を下げてしまった。また、試料Ｎｏ．１６〜１８はミラー表面上の汚れが広がってしまい清浄効率が下がり反射率を下げてしまった。
従って、水を使用せず太陽熱反射装置のミラー表面を気体により清浄する手法によって、ミラー表面に傷を付けずに清浄を行えるだけではなく、汚れの再付着を防止できることがわかる。

As can be seen from Table 2, it can be seen that the method of cleaning the solar power generation reflecting device according to the present invention is superior to the comparative example.
Sample No. which is a comparative example. Since No. 13 is cleaned only by the blower, the deposits that have risen after blowing are reattached on the mirror, and the reflectance is lowered. Sample No. In Nos. 16 to 18, dirt on the mirror surface spreads, the cleaning efficiency is lowered, and the reflectance is lowered.
Therefore, it can be seen that the method of cleaning the mirror surface of the solar heat reflecting device with gas without using water can not only clean the mirror surface without scratching it but also prevent the reattachment of dirt.

DESCRIPTION OF SYMBOLS 1 Surface layer 2 Translucent resin layer 3A Flat white plate glass 3B Resin film-like support body 4 Light reflection layer 5 Corrosion prevention layer 6 Adhesion layer 7 Support substrate 10A Glass light reflection mirror 10B Resin reflection mirror 20A Reflector for solar power generation A
20B Solar power generator reflector B
21 Holding member (column)
22B Reflector unit B for solar power generation
30 trough-type solar power generation reflector 31 heat collecting pipe 32 transport pipe 33 heat exchange device 40 air blower 41 wind direction adjusting member 41a upper wind direction adjusting member 41b lower wind direction adjusting member 42 static eliminator 50 dust collecting device 51 dust collecting part 52 gripping member 60 supporters

Claims (7)

It is a cleaning method for a solar thermal power generation reflection device that cleans with a gas a solar power generation reflection device that includes a light reflection mirror that reflects sunlight having a surface layer with a water contact angle in the range of 80 to 170 °. ,
A blower and a dust collector are provided near the light reflecting mirror,
While moving at least one of the blower and the dust collector on the light reflecting mirror surface,
A solar power generation reflecting device characterized in that air is blown toward the light reflecting mirror surface from the air blowing device, and the deposits removed from the light reflecting mirror surface by air blowing are collected by the dust collecting device. Cleaning method. The said light reflection mirror has a light reflection layer on a resin-made base material, The cleaning method of the reflective apparatus for solar power generation of Claim 1 characterized by the above-mentioned.   The device that moves on the light reflecting mirror is the air blowing device and the dust collecting device, and at least one device that moves on the light reflecting mirror has a static eliminator, while neutralizing the surface of the light reflecting mirror The cleaning method for a solar power generation reflecting device according to claim 1, wherein the cleaning device is moved.   The method for cleaning a solar power generation reflecting device according to any one of claims 1 to 3, wherein a wind speed of the air discharged from the blower is 5 to 80 m / s. A solar power generation reflecting device cleaning system for cleaning a light reflecting mirror that reflects sunlight provided in a solar power generation reflecting device with gas,
The light reflecting mirror has a surface layer whose water contact angle is in the range of 80 to 170 °,
A blower and a dust collector are provided near the light reflecting mirror,
While moving at least one of the blower and the dust collector on the light reflecting mirror surface,
A solar power generation reflecting device characterized in that air is blown toward the light reflecting mirror surface from the air blowing device, and the deposits removed from the light reflecting mirror surface by air blowing are collected by the dust collecting device. Clean system. A solar thermal power generation system having a plurality of light reflecting mirrors for reflecting sunlight and a cleaning device for cleaning the surface of the light reflecting mirror,
The cleaning device has a water contact angle on the surface of the reflection mirror in the range of 80 to 170 °, and has a blower and a dust collector for installation near the surface of the reflection mirror,
While moving at least one of the blower and the dust collector on the light reflecting mirror surface,
The solar power generation system, wherein air is blown toward the surface of the light reflecting mirror from the blower, and the deposits removed from the surface of the reflecting mirror by the blow are collected by the dust collector. A solar power generation reflector cleaning device for cleaning a light reflecting mirror provided in a solar thermal power generation system,
While moving at least one of the blower and the dust collector on the light reflecting mirror surface,
The dust collected by the dust collector is collected from the surface of the light reflecting mirror that is blown by a wind within a range of wind speed of 5 to 80 m / s from the blowing device toward the reflecting mirror surface. A cleaning device for a solar thermal power generation reflector.

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