JP2017104819A - Water washing system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To suppress the generation of scales of hardness components or silica on a surface when a washing object having glass over the whole or a part of the surface is to be washed with water.SOLUTION: A water washing system, which washes a washing object having glass over the whole or a part of the surface, comprises a water treatment apparatus that adds a chelate agent which blockages silica components in water to washing water for washing the washing object and a sprinkling apparatus that sprinkles washing water to which the chelate agent is added to the washing object. When being a cooling and washing system of a photovoltaic power generation panel, the water washing system can function to improve power generation efficiency by cooling and washing and further prevent the power generation efficiency from being decreased by sprinkling the cooling and washing water itself.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a water cleaning system for cleaning an object having glass on all or part of its surface, and more particularly to a water treatment technique for cleaning an object to be cleaned.

  For example, solar power generation, which is one of renewable energies, is widely used both in Japan and overseas. Photovoltaic power generation panels that convert sunlight into electricity have been put into practical use, ranging from large-sized ones constituting mega solar to relatively small ones installed on the roofs of houses and apartments.

The power generation effect of the photovoltaic power generation panel is generally said to decrease to about 60% after 10 years and to about 50%, which is half after 20 years, with the output gradually decreasing after installation. There are the following three main causes of the output decrease.
(1) Output reduction (10-15%) due to increase in surface temperature of photovoltaic panels
(2) Output reduction (3-9%) due to dirt on the surface of the solar panel
(3) Output reduction (1-3%) due to snow accumulation on the daylighting surface of the solar power generation panel

  For example, even in Japan, the temperature of the panel surface may rise to close to 70 ° C in the summer, and to reduce power generation efficiency due to the temperature rise, water has been sprayed on the photovoltaic power generation panel. Solutions by cooling are being studied. Furthermore, in order to reduce water consumption, it has been studied to collect and purify the sprinkled water and spray it again, or to use rainwater instead of clean water as a water source (for example, Patent Documents 1 to 3). 3).

JP 2012-54340 A Japanese Patent No. 3751013 JP2013-38102A

  However, when water is sprayed on the panel surface, there is a problem that scales such as hardness components and silica contained in the water are generated on the panel surface. If a scale such as a hardness component or silica is generated on the panel surface, it may adversely affect the daylighting of sunlight and cause a decrease in power generation efficiency. FIG. 8A is a photograph of a scale generated on the panel surface when water is actually sprinkled using a spray nozzle type watering device. According to Fig.8 (a), it can confirm that the cloudy scale generate | occur | produces in the spot shape on the panel surface. This is a state only 30 days after the start of watering. Thus, the scale generated by water spraying on the panel surface whose temperature has risen is chemically bonded to the glass on the panel surface and cannot be easily removed by washing with water or wiping. In FIG. 8B, the scale is removed by wiping, but the state of the panel surface is deteriorated.

  That is, for example, in the technology disclosed in Patent Documents 1-3, only the photovoltaic power generation panel is cooled with water, and the problem of the scale that becomes apparent by actually watering is not examined at all. . In other words, high power generation efficiency can be obtained in the initial stage after the start of watering, but the power generation efficiency gradually decreases due to the generation and accumulation of scale over the long term. As described above, it is difficult to remove the scale if it accumulates. Such a scale problem becomes prominent particularly when a large number of large photovoltaic panels are installed on a large site.

  The problem of scale caused by watering becomes a problem in technical fields other than photovoltaic panels. For example, when water is sprinkled to clean a building such as a condominium or a public facility, or a vehicle such as a train or a car, scale is generated on the surface. In particular, when a scale derived from silica is generated on the surface of the window glass, it is difficult to remove the scale. FIG. 9 is an image of a scale generated on a window glass due to watering.

  The present invention has been made in order to solve the above-mentioned problems mentioned as an example. The purpose of the present invention is to clean the surface of the object having glass on all or part of the surface with a hardness component or It aims at suppressing generation | occurrence | production of scales, such as a silica.

  Another object of the present invention is to provide a cooling and cleaning system for a photovoltaic power generation panel that can perform cooling and cleaning functions for the photovoltaic power generation panel by sprinkling cooling and cleaning water, and can greatly improve power generation efficiency. (In the snowfall area, it also performs a snow removal function). In particular, it is intended to suppress the generation of scales such as hardness components and silica on the surface of a daylighting portion of a photovoltaic power generation panel that is an object to be cleaned, and to prevent power generation efficiency from being reduced due to water spray.

(1) The water cleaning system of the present invention is a water cleaning system for cleaning an object to be cleaned having glass on all or a part of its surface, and the silica is submerged in the cleaning water for cleaning the object to be cleaned. A water treatment device for adding a chelating agent for blocking components and a watering device for spraying the washing water to which the chelating agent is added to an object to be cleaned are provided.
The "chelating agent that sequesters the silica component in water" is not specified as a chelating agent that exerts an action of sequestering only the silica component in water, but is one of iron, manganese, and hardness components together with the silica component in water. Also included are chelating agents that act to sequester species or more.
(2) The water cleaning system is a cooling and cleaning system for improving the power generation efficiency of the photovoltaic power generation panel, and is used as cleaning water for cooling and cleaning the surface of the daylighting portion of the photovoltaic power generation panel that is the object to be cleaned. A water treatment device for adding a chelating agent that sequesters a silica component in water, a watering device for sprinkling the cleaning water to which the chelating agent has been added to a solar power generation panel, and cooling and cleaning the solar power generation panel; A water collecting device that collects water to reuse the cleaning water sprayed on the solar power generation panel can be provided.
(3) It is preferable that the chelating agent added to the washing water contains dihydroxyethylglycine sodium salt and / or 1-hydroxyethylidene-1,1-diphosphonic acid.
(4) It is preferable to add the chelating agent so as to be 10% by mass or more with respect to the washing water.
(5) A pretreatment device that removes suspended solids (SS), iron, manganese, and hardness components so that the evaporation residue of cleaning water sprayed on the object to be cleaned is 200 mg / L or less; It can arrange | position in the front | former stage rather than the water treatment apparatus which adds.

  According to the water cleaning system of the present invention, the surface of the object to be cleaned having glass on all or a part of the surface is sprayed by spraying the cleaning water to which the chelating agent that blocks the silica component in water is added. Generation | occurrence | production of scales, such as a hardness component and a silica, can be suppressed.

  In addition, when the water cleaning system is a photovoltaic panel cooling and cleaning system, it performs the function of improving power generation efficiency by cooling and cleaning, and the power generation efficiency decreases due to the spraying of cooling and cleaning water itself. Can be prevented. The function of improving the power generation efficiency by cooling and washing can obtain a higher effect on the photovoltaic power generation panel installed in an area where the temperature is high overseas.

  Furthermore, if the chelating agent added to the washing water contains dihydroxyethylglycine sodium salt and / or 1-hydroxyethylidene-1,1-diphosphonic acid, as is clear from the results of the examples described later, The effect of suppressing the generation of scale is great.

  Preferably, the chelating agent added to the washing water is added so that the concentration of the chelating agent is 10% by mass or more of the silica content contained in the washing water. By adjusting to such a concentration, generation of scale can be suppressed more reliably.

  More preferably, a pretreatment device for removing suspended solids (SS), iron, manganese, and hardness components is provided so that the evaporation residue of cleaning water sprayed on the object to be cleaned is 200 mg / L or less, and chelate is provided. Pre-treat the wash water before adding the agent. By performing this pretreatment, the blocking action of the chelating agent can be effectively applied to the silica, and the generation of scales in which the glass and silica on the panel surface are chemically bonded can be more reliably suppressed. it can. In addition, by performing the pretreatment, it is possible to suppress the generation of scale due to a different element other than silica.

It is a cooling and washing | cleaning system of the photovoltaic power generation panel according to 1st Embodiment of this invention. It is a figure explaining the watering apparatus and water collecting apparatus of the said cooling and washing system. It is a water washing system according to a 2nd embodiment of the present invention. It is a figure which shows the result of Example 1 performed in order to confirm the effect of this invention. It is a figure which shows the result of Example 1 performed in order to confirm the effect of this invention. It is a figure which shows the result of the comparative example performed in order to confirm the effect of this invention. It is a figure which shows the result of Example 2 performed in order to confirm the effect of this invention. It is a figure explaining the scale which generate | occur | produced on the surface of the photovoltaic power generation panel. It is a figure explaining the scale which generate | occur | produced on the surface of the window glass of a building.

  Hereinafter, a water washing system according to a preferred embodiment of the present invention will be described with reference to the accompanying drawings. However, the technical scope of the present invention is not construed as being limited by the embodiments described below.

(First embodiment)
FIG. 1 is a diagram showing an overall configuration of a cooling and cleaning system 2 (hereinafter simply referred to as a “cooling and cleaning system”) for a photovoltaic power generation panel 1 according to the first embodiment. As shown in FIG. 1, the cooling and cleaning system 2 includes a storage tank 3 for storing water for cooling and cleaning (referred to as “cooling and cleaning water” in this specification), and cooling and cleaning in the photovoltaic power generation panel 1. A water sprinkling device 4 for sprinkling water, a water collecting device 5 for collecting the sprinkled cooling and washing water, and a reuse device 6 for making the collected cooling and washing water reusable are provided. As shown in FIG. 1, the storage tank 3, the water spray device 4, the water collection device 5, and the reuse device 6 form a loop that circulates and uses cooling and washing water, thereby suppressing water consumption. ing. However, since loss due to evaporation or the like occurs, the cooling and cleaning system 2 includes a makeup water path 7 for compensating for the loss. As cooling / washing water and its replenishing water, it is preferable to use natural environment water such as ground water, river water, and lake water in order to effectively use water resources. In addition, industrial water and tap water can also be used, but these have disadvantages that are expensive.

  Natural water, such as groundwater, river water, and lake water, contains suspended solids, metal ions such as iron, manganese, calcium, magnesium, silica, and organic matter that cause scale. The route 7 includes a chelating agent addition device 8 for adding a chelating agent capable of sequestering these components to the cooling and washing water, and a pretreatment device 9 for performing a predetermined pretreatment before adding the chelating agent. Has been placed. Hereinafter, each device will be described in detail.

  The watering device 4 is a device that sprays cooling and washing water toward the surface of the photovoltaic power generation panel 1. The general structure of the photovoltaic power generation panel 1 is a panel structure in which a large number of solar cells are arranged on a frame member such as aluminum, and the panel surface on the daylighting side is covered with a transparent member such as glass. There is also a photovoltaic power generation panel having a structure in which a solar cell is formed on one surface of a transparent member. The water sprinkling device 4 sprinkles cooling / washing water toward the surface of the transparent member that forms the surface of the sunlight daylighting unit.

  As a preferred example of the watering device 4, a spray nozzle type watering device 41 as shown in FIG. However, it is not limited to the configuration shown in FIG. 2, and a known watering means such as a sprinkler or a shower type can be employed. Moreover, piping can be installed along one side above the panel, and water can be sprayed from a plurality of discharge holes provided in the piping.

  As shown in FIG. 2, the spray nozzle type watering device 41 is installed, for example, at the center of one side on the lower side of the large-sized photovoltaic power generation panel 1 and swivels the nozzle head while spraying the cooling and washing water W. By doing so, the cooling and washing water W is sprayed over the entire panel surface. In the case where a plurality of photovoltaic power generation panels 1 are installed in the site, the cooling and washing water in the storage tank 3 is sent to each of the sprinklers 4 using a pump, and the nozzle head is utilized using the discharge pressure of the pump. Can be injected from.

  About watering time and the amount of watering, it is preferable to adjust suitably while actually operating. As an example of the watering time, for example, the panel surface temperature is monitored with a thermometer, and when a predetermined temperature (for example, 50 ° C.) is exceeded, watering is started, or the predetermined time of the sunshine time (for example, between 12:00 and 14:00) ) You may make it water. Furthermore, as an example of the watering amount, for example, watering may be performed at a flow rate of 2 to 4 L / Hr per panel unit area. Even in the winter when the temperature is low, water may be sprayed for the purpose of solving snow accumulated on the panel.

  The water collecting device 5 is a device that collects cooling and washing water for reuse. As an example of the water collecting device 5, as shown in FIG. 2, for example, a ridge 51 is arranged along one side on the lower side of the panel, and the cooling and washing water flowing down on the inclined panel surface is received by the ridge 51. Can be configured. In the case where a plurality of photovoltaic power generation panels 1 are installed in the site, the solar power generation panels 1 are collected in a water collection tank (not shown) through piping or the like connected to the fence 51 arranged on each panel. However, it is not limited to the configuration of FIG. 2, and a known water collecting method such as constructing a water channel (recovery channel) on the site surface can be employed. By providing the water collecting device 5 in this way, not only the consumption of cooling and washing water can be suppressed, but also the rain water that has fallen on the panel surface during rainy weather can be taken in as cooling and washing water.

  In addition, since it is often not sprinkled during rainy weather, in this case, it is also possible to collect only rainwater with a water collecting device and send it to the replenishing water path 7 to perform pretreatment and chelating agent addition. Or since rainwater has few components which cause a scale, you may abbreviate | omit a pretreatment and a chelating agent addition.

  The reuse device 6 is a device for processing the recovered cooling and washing water so that it can be reused. The cooling / cleaning water that serves as both cooling and cleaning contains dirt adhering to the panel surface. This dirt may block the nozzle head of the sprinkler 4 or cause water quality deterioration such as breeding of various bacteria. Therefore, for example, the reusable device 6 is configured by a filter or the like to remove suspended substances and the like contained in the cooling and washing water collected. As an example of a filter, a microfilter or the like can be employed. Since the cooling and cleaning system 1 of the present embodiment suppresses the generation of scale by performing pretreatment and addition of a chelating agent in advance, it can be reused simply by removing suspended substances and the like thereafter. There are advantages. However, the reuse device 6 can also be configured by combining devices necessary for maintaining water quality, such as a sterilization device that suppresses the propagation of germs. Furthermore, when the temperature of the recovered cooling / washing water is high, a cooling device may be further added.

  Next, the pretreatment device 9 and the chelating agent addition device 8 arranged in the makeup water path 7 will be described. As already mentioned, natural environment water such as groundwater, river water, lake water, etc. contains metal ions such as iron, manganese, calcium, magnesium, silica, and organic matter, including suspended solids. The components are repeatedly cooled and washed to form inorganic and organic scales on the surface of the photovoltaic power generation panel 1. As a countermeasure, in the present embodiment, a pretreatment device 9 and a chelating agent addition device 8 are arranged.

  The pretreatment device 9 is composed of a filter that removes suspended substances contained in the taken natural environment water, an ion exchange resin device that removes iron and manganese, and a water softening device that removes hardness components. As a result of actually performing the evaluation test, by removing suspended solids, iron, manganese, and hardness components so that the evaporation residue of cooling and washing water sprayed on the photovoltaic power generation panel 1 is 200 mg / L or less. It has been confirmed through actual tests that the suppression effect of scale generation is enhanced.

  That is, scale evaluation is effectively suppressed by comprehensively evaluating the evaluation items of the pretreatment with the evaporation residue in combination with the concentrations of individual metal ions, suspended substances or organic substances. The pre-processing device 9 only needs to be configured by a device that can satisfy this requirement, and the type of each device is not limited. For example, a catalytic oxidation apparatus may be adopted as an apparatus for removing iron and manganese, and when an oxidizing agent is added, an activated carbon tower can be additionally arranged.

  On the other hand, instead of the evaporation residue, the concentration of a specific component may be used as an index. As an example, pretreatment is performed so that the suspended solids are 1 mg / L or less, iron is 0.01 mg / L or less, manganese is 0.01 mg / L or less, and the hardness component is 2 mg / L or less.

  Next, the chelating agent addition device 8 is a device that prepares cooling and washing water by adding a predetermined chelating agent to the natural environmental water after the pretreatment. The chelating agent to be added is selected from those that exhibit an action of blocking the silica component in water. Particularly preferred is a chelating agent containing dihydroxyethylglycine sodium salt and 1-hydroxyethylidene-1,1-diphosphonic acid as components. These chelating agents can sequester metal components such as iron, but have a characteristic property that silica components can be sequestered in water, which is not found in general chelating agents. One type of chelating agent may be added, or two or more types may be added. As a chelating agent containing dihydroxyethylglycine sodium salt or 1-hydroxyethylidene-1,1-diphosphonic acid as a component, for example, a liquid commercially available one can be used.

  The chelating agent addition device 8 can be constituted by, for example, an agitation layer equipped with a stirring means, an inline type agitation device such as a line mixer, or the like. As another example, a tank for storing the natural environment water that has been pretreated may be installed, and a chelating agent may be introduced into the tank. The addition amount of the chelating agent is, for example, 10% by mass or more, preferably 10% by mass to 80% by mass, and more preferably 20% by mass to 30% by mass with respect to the silica content contained in the washing water. If the amount added is small, silica components that cannot be blocked may remain, whereas if the amount added is too large, the running cost becomes high.

  However, even when rainwater is taken in as cooling and washing water, the addition amount may be set to be large so that components contained in rainwater can be blocked. Further, when a chelating agent is added, depending on the pH of the cooling and washing water, the components blocked in the water may be solidified and precipitated, so the pH may be adjusted by adding an acid or alkali. The cooling / washing water thus prepared is sent to the storage tank 3 and sprinkled on the photovoltaic power generation panel 1 through the watering device 4.

(Function)
A procedure for cooling and cleaning the photovoltaic power generation panel 1 using the cooling and cleaning system 2 described above will be described. First, during the initial operation of the system, water (preferably natural environment water) as a raw material is taken into the makeup water path 7, pretreatment and addition of a chelating agent are performed to prepare cooling and washing water. The prepared cooling and washing water is stored in the storage tank 3. Next, when the conditions that require watering are met while the photovoltaic power generation panel 1 is generating power, the watering device 4 is activated to start watering.

  In the case of the spray nozzle type watering device 41 shown in FIG. 2, cooling and washing water is sprayed toward the panel surface, and cooling and washing are performed while flowing down the surface. The cooling and washing water is pre-treated so that the evaporation residue is less than the predetermined amount, and the silica component is blocked by the chelating agent, so the component causing the scale adheres to the panel surface. Do not run down. Alternatively, even if moisture evaporates and remains on the panel surface, it is washed away by subsequent cooling and washing water.

  In particular, when a chelating agent consisting of dihydroxyethylglycine sodium salt or 1-hydroxyethylidene-1,1-diphosphonic acid is employed, it exhibits not only a blocking action but also a surface-active action, and the panel surface is smooth and uneven. It can flow and cool and clean. Such a surface active action is an advantageous effect discovered by actually conducting a test. On the other hand, when no chelating agent is added, the cooling and washing water sprayed on the panel surface often flows in a concentrated manner on the surface of the panel due to surface tension, resulting in uneven cooling and washing. Also confirmed.

  The cooling / washing water that has flowed down the panel surface is collected by the water collecting device 5 and sent to the reuse device 6. In the reuse device 6, dirt such as suspended substances and foreign matters is removed. The reused cooling / washing water is returned to the storage tank 3. On the other hand, the cooling / washing water used for circulation causes a loss such as evaporation, so that natural environment water for compensating for the loss is taken into the replenishing water path 7 to prepare the cooling / washing water for replenishment.

  According to the cooling and washing system 2 described above, the chelating agent that exerts the action of blocking the silica component in water such as dihydroxyethylglycine sodium salt and 1-hydroxyethylidene-1,1-diphosphonic acid is used as the cooling and washing water. By adding and watering the solar power generation panel 1, it is possible to suppress the generation of scales such as hardness components and silica on the panel surface, as is apparent from the test results described later. As a result, while improving the power generation efficiency by cooling and washing, it is possible to prevent the power generation efficiency from being lowered due to the sprinkling of the cooling and washing water itself. Further, the cooling and cleaning system 2 of the present embodiment has an advantage that it can be realized in a compact and low cost in addition to high performance cooling and cleaning.

  More preferably, by removing suspended substances, iron, manganese, and hardness components so that the evaporation residue is 200 mg / L or less by pretreatment, an inorganic or organic scale other than silica is generated. Can be prevented. Furthermore, by performing the pretreatment prior to the addition of the chelating agent, the blocking action of the chelating agent can be effectively exerted on the silica, and the scale of the glass and silica on the panel surface is chemically bonded. The effect which suppresses generation | occurrence | production more reliably increases.

(Second Embodiment)
Next, a water cleaning system according to the second embodiment will be described with reference to FIG. The water cleaning system 10 according to the present embodiment is a water cleaning system whose main function is cleaning. As shown in FIG. 3, the water cleaning system 10 according to the present embodiment has the same configuration as that of the first embodiment except that the object to be cleaned is not a photovoltaic power generation panel. Therefore, detailed description is omitted by giving the same reference numerals.

  An object to be cleaned in this embodiment is an object having glass on all or part of its surface. Examples include buildings such as apartments and public facilities, and vehicles such as trains and cars. For example, when the building is an object to be cleaned, it may be difficult to collect the cleaning water. Therefore, the system configuration without the water collecting device 5 and the reuse device 7 may be adopted. Furthermore, when water consumption is small, industrial water or clean water can be used as a water source. Even in the second embodiment having such a configuration, it is possible to suppress the occurrence of scale for the same reason as in the first embodiment. Needless to say, the object to be cleaned is not limited, and if the entire or part of the surface has glass, the object can be cleaned.

Then, Example 1 performed in order to confirm the effect of this invention is demonstrated.
In this example, pretreatment and addition of a chelating agent were performed to prepare cooling / washing water, and water was actually sprinkled on the surface of the solar cell panel to confirm the occurrence of scale. For comparison, a similar test was performed using cooling and washing water that was only pretreated and no chelating agent was added.

  Prior to the test, the effects of iron, manganese and hardness components on evaporation residue and scale adhesion were confirmed. Specifically, the tap water containing about 70 mg / L hardness component is added with iron and manganese standard reagents (1000 mg / L), and the raw water is made to have an iron concentration and a manganese concentration of 1 mg / L respectively. The treated water was prepared by further removing iron and removing manganese and treating the hardness component. That is, the treated water which gave the process equivalent to a pre-process was obtained. Then, an evaporation residue test was performed for each of the raw water and the treated water, and the amounts of iron, manganese, hardness, and evaporation residue were measured. The results and photographs are shown in FIG. From the results of FIG. 4, it can be seen that pretreatment can suppress the generation of scale due to iron, manganese, and hardness components. The evaporation residue of raw water had a red rust color because it contained iron.

  Subsequently, the silica concentration of the above-mentioned treated water was adjusted to 100 mg / L using a silica standard solution, and a chelating agent was further added to 30% of the silica content to prepare cooling and washing water for Examples. As the chelating agent, a solution of dihydroxyethylglycine sodium salt (manufactured by Chubu Kirest Co., Ltd., trade name: Kirest G-50) was used. Furthermore, the water without addition of a chelating agent was used as cooling and washing water for a comparative example.

  The photovoltaic power generation panel (model: AT-MA5A) manufactured by Autumn Technology Co., Ltd. was used as the photovoltaic power generation panel for spraying the cooling and washing water. The nominal maximum output is 5 W, and the outer dimensions are 185 × 250 × 15 mm. Two photovoltaic power generation panels were prepared for the example and the comparative example. In both the examples and comparative examples, spraying was continued until 200 mL of cooling and washing water disappeared, and it was confirmed whether or not scale due to the silica component was generated on the panel surface. In order to reproduce the summer condition, the solar power generation panel was heated with the radiant heat of the heater. The results are shown in FIGS.

  As is clear from the results of FIG. 5, in Example 1 in which the cooling and washing water added with the chelating agent was sprinkled, the generation of scale due to the silica component could not be confirmed. On the other hand, as is clear from the results of FIG. 6, in the comparative example in which the chelating agent was not added, a scale due to the silica component was generated on the entire panel surface. That is, it was confirmed that generation of scale of the silica component can be suppressed by adding the chelating agent.

  This example is Example 2 in which a test similar to Example 1 was performed using three types of chelating agents. In Example 1, 30% of the silica content of the chelating agent was added. In Example 2, cooling and washing water added with 10% and 20% was prepared and the same test was performed. The result is shown in FIG. As is clear from the results of FIG. 7, it was confirmed that the use of dihydroxyethylglycine sodium salt and 1-hydroxyethylidene-1,1-diphosphonic acid can suppress the generation of scale of the silica component. However, since the effect may be insufficient when it is 10%, it was confirmed that it is preferably 20% or more in order to obtain a more reliable effect. On the other hand, when ethylenediaminetetraacetic acid tetrasodium tetrahydrate was used, it was also confirmed that generation of scale of the silica component could not be suppressed.

DESCRIPTION OF SYMBOLS 1 Photovoltaic power generation panel 2 Cooling and washing system 4 Sprinkling device 5 Water collecting device 8 Chelating agent addition device 9 Pretreatment device 10 Water washing system

(1) The water cleaning system of the present invention is a water cleaning system for improving the power generation efficiency of a solar power generation panel, and is used as cooling and cleaning water for cooling and cleaning the surface of a daylighting portion of the solar power generation panel. A water treatment device for adding a chelating agent that sequesters a silica component in water, and water for cooling and washing the solar power generation panel by spraying the cooling and washing water to which the chelating agent has been added to the solar power generation panel. And a water collecting device for collecting water to reuse the cooling and washing water sprayed on the photovoltaic power generation panel .
The "chelating agent that sequesters the silica component in water" is not specified as a chelating agent that exerts an action of sequestering only the silica component in water, but is one of iron, manganese, and hardness components together with the silica component in water. Also included are chelating agents that act to sequester species or more.
( 2 ) The chelating agent added to the cooling and washing water preferably contains dihydroxyethylglycine sodium salt and / or 1-hydroxyethylidene-1,1-diphosphonic acid.
(3) the chelating agent, to the cooling and washing water, it is preferably added so as to be 10 mass% or more silica content contained in the cooling and washing water.
( 4 ) A pretreatment device that removes suspended solids (SS), iron, manganese, and hardness components so that the evaporation residue of cooling and washing water sprayed on the photovoltaic power generation panel is 200 mg / L or less, It can arrange | position ahead of the water treatment apparatus which adds the said chelating agent.

Claims (5)

A water cleaning system for cleaning an object having glass on all or part of its surface,
A water treatment apparatus for adding a chelating agent that sequesters the silica component in the water to the washing water for washing the object to be washed;
A water cleaning system, comprising: a watering device that sprays the cleaning water to which the chelating agent is added to an object to be cleaned. The water cleaning system is a cooling and cleaning system for improving the power generation efficiency of the photovoltaic power generation panel,
The water treatment device for adding a chelating agent that sequesters the silica component in the water to the washing water for cooling and washing the surface of the daylighting portion of the photovoltaic power generation panel that is the object to be washed
Sprinkling the cleaning water to which the chelating agent has been added to a solar power generation panel, and cooling and cleaning the solar power generation panel;
The water washing system according to claim 1, further comprising: a water collecting device that collects water to reuse the washing water sprayed on the solar power generation panel.   The water washing system according to claim 1 or 2, wherein the chelating agent added to the washing water contains dihydroxyethylglycine sodium salt and / or 1-hydroxyethylidene-1,1-diphosphonic acid.   The said chelating agent is added so that it may become 10 mass% or more of the silica content contained in the washing water with respect to the said washing water. Water washing system. The chelating agent is added to a pretreatment device that removes suspended solids (SS), iron, manganese, and hardness components so that the evaporation residue of washing water sprayed on the object to be cleaned is 200 mg / L or less. The water washing system according to any one of claims 1 to 4, wherein the water washing system is disposed upstream of the water treatment apparatus.