KR100829825B1 - A method for ice keeping in reservoir - Google Patents

Abstract

The present invention relates to an ice storage device and an ice storage method for a reservoir for maintaining a low amount of water to form a thick ice layer by raising water below the ice layer above the ice layer at sub-zero temperatures.

To this end, the present invention, the preparation step (S100) for installing a water pump 300 for raising the water of the reservoir 100 is stored water; After the ice layer 200 is formed on the surface of the reservoir 100, the pumping step 300 to operate the pumping device 300 to raise the water below the ice layer 200 to the upper side of the ice layer 200 and (S200); An ice cube step (S300) of spraying water drawn up to the pumping device (300) on the upper surface of the ice layer (200) and freezing water on the upper surface of the ice layer (200) by cold air in a natural state; It is configured to include a frost control step (S400) to control the operation of the pumping device 300 according to the weather conditions such as solar radiation and precipitation to continuously thicken the ice layer 200. According to the present invention having such a configuration, it is possible to secure a low amount of the reservoir 100 by suppressing evaporation, thereby preventing the shortage of water resources and conserving water quality.

Reservoir, reservoir, ice, ice, drought, evaporation suppression, water quality

Description

A method for ice keeping in reservoir}

1 is a schematic view schematically showing a preferred embodiment of the reservoir ice storage method according to the present invention.

Figure 2 is a schematic diagram schematically showing a preferred embodiment of the ice storage method of the reservoir in which the icy ice storage according to the present invention is installed.

Figure 3 is a schematic diagram showing the configuration of the pumping mechanism of a preferred embodiment of the reservoir method of the reservoir according to the present invention.

Figure 4 is a flow chart showing step by step a preferred embodiment of the reservoir ice storage method according to the present invention.

* Description of the symbols for the main parts of the drawings *

100. Reservoir 120. Float

140. Ice Shelter 200. Ice Layer

300. Pumping mechanism 310. Pumping pipe

320. Injection means 330. Support members

340. Driving means 350. Power supply means

400. Bypass piping 500. Jang Ice Station piping

S100. Preparation step S110. First stage of preparation

S120. Preparation step S200. Pumping stage

S300. Ice step S400. Ice control step

S500. Thawing stage

The present invention relates to a storage method for reservoirs for low water retention and water conservation, which enables low water retention and water quality conservation by raising water below the ice layer above the ice layer to form a thick ice layer at subzero temperatures.

In general, reservoirs are used to store excess water to control excess or underwater, ranging from small ponds for use as agricultural water to large dams for drinking water supply and power generation.

Such a reservoir is mainly used to store water in rainy season with heavy rainfall, to prevent flooding or flooding of rivers, and to release water in the low-drained dry season so that it can be used as agricultural water or drinking water.

Therefore, the need for such reservoirs will be even greater in areas with frequent heavy rains or in areas with high rainfall and low rainfall during the rainy season. In particular, in the spring season when agricultural water and drinking water are needed, many people may experience inconveniences due to the lack of water, as well as a devastating effect on the cultivation of crops. It is just repeated every year.

In order to solve such a problem, a sufficient amount of reservoirs must be secured. For this purpose, more reservoirs must be constructed or the reservoir must be larger in size.

However, the construction of more new reservoirs takes a lot of time and money, and in particular, the construction of large reservoirs has a problem of astronomical costs.

In addition, for the construction of reservoirs, it is necessary to consider the impact on the surrounding environment, as well as to solve all the large and small problems such as compensation problems caused by the construction of new reservoirs, damage to the landscape, and loss of cultural property. However, the construction of many reservoirs in a limited land area is not only inefficient, but there will be no infinite number of places suitable for the construction of reservoirs.

On the other hand, even if the number of reservoirs is increased, precipitation is low every year during the dry seasons of winter or spring, and the amount of evaporation is high, so the reservoir amount of the reservoir is continuously reduced through a huge amount of evaporation. Due to this phenomenon, the bottom of the reservoir is exposed before the rainy season almost every year, which cannot be solved by simply increasing the number of reservoirs or constructing a large dam.

As a result, the limited reservoir is unable to provide sufficient water in the early spring season, and there is a problem in that it is not possible to secure a sufficient amount of water to solve the shortage of agricultural and living water due to drought. In addition, problems such as water quality is contaminated due to the growth of phytoplankton due to the rise in water temperature in summer.

Therefore, an object of the present invention is to solve the problems of the prior art as described above, by raising the water below the ice layer above the ice layer at sub-zero temperatures to form a thick ice layer continuously to maintain the water quality and storage of the reservoir It is to provide a storage method of the reservoir.

The ice storage method of the reservoir for achieving the above object comprises the steps of preparing a pumping mechanism for raising the water of the reservoir in which the water is stored; After the ice layer is formed on the surface of the reservoir water pumping step of operating the pumping device to raise the water under the ice layer above the ice layer; An ice-ice step of spraying the water drawn up by the pumping device onto the upper surface of the ice layer and freezing the water on the upper surface of the ice layer by cold air in a natural state; It comprises a frost control step of adjusting the operation of the pumping device according to the weather conditions such as solar radiation and precipitation so that the ice layer is continuously thickened.

In the preparation step, when the ice layer is not formed on the surface of the reservoir, it floats a float having a certain surface area on the surface of the reservoir to promote freezing.

In the preparation step, if the ice layer is not formed on the surface of the reservoir, it is characterized in that the ice is supplied to the ice maker or snow plow on the surface of the reservoir to promote freezing.

In the preparation step, it is characterized in that it is formed on the one side of the reservoir is a shelter which is a space that can be stored by freezing the cold water by pulling up the water of the reservoir.

The shelter is formed at the edge of the reservoir, is formed at a position higher than the water surface of the reservoir, it characterized in that the shield member is further provided to prevent sunlight and rain.

In the frosting step, it is characterized in that the spraying means for injecting the water drawn up by the pumping device in a small particle state from the top of the ice layer.

In the icing control step, when the temperature rises in the image or rains, the operation of the pumping device is characterized in that to stop.

After all of the ice layer is melted, the ice stored in the ice sheet melts and flows into the reservoir, thereby lowering the water temperature of the reservoir water, characterized in that the thawing step is further performed.

In addition, the ice storage method of the reservoir for maintaining the storage amount to achieve the above object is, the water is formed by spraying water on the surface of the reservoir and the outer surface of the reservoir formed on the adjacent one side of the reservoir where the water is stored to cause freezing 1 preparation step; A second preparation step of installing a pumping device in the ice layer formed by the first preparing step, and continuously installing the pumping device as freezing proceeds to the inside of the reservoir; After the ice layer is formed on the surface of the reservoir water pumping step of operating the pumping device to raise the water under the ice layer above the ice layer; An ice-ice step of spraying the water drawn up by the pumping device onto the upper surface of the ice layer and freezing the water on the upper surface of the ice layer by cold air in a natural state; It comprises a frost control step of adjusting the operation of the pumping device according to the weather conditions such as solar radiation and precipitation so that the ice layer is continuously thickened.

In the first preparation step, the water is supplied to the inside of the janggeokgo by the janggeokso pipe separately provided in the janggeokgo characterized in that the icing occurs inside the janggeokgo.

In the frosting control step, the pumping mechanism is continuously operated so that the water of the reservoir is bypassed by a bypass pipe connected to the pumping mechanism, and connected to the lower portion of the reservoir.

According to the ice storage method of the reservoir for maintaining the storage amount according to the present invention having such a configuration, there is an effect that can secure sufficient water resources by minimizing the amount of evaporation of the reservoir by the formation of ice layer to preserve the reservoir amount.

Hereinafter, with reference to the accompanying drawings the ice storage method of the reservoir for the storage of water storage according to the present invention having the above configuration will be described in more detail.

1 is a schematic view schematically showing a preferred embodiment of the reservoir ice storage method for the storage of the reservoir according to the present invention, Figure 2 is the initial formation of ice layer according to a preferred embodiment of the reservoir ice storage method for the storage of the reservoir according to the present invention A schematic diagram showing the process. And, Figure 3 is a schematic diagram showing a schematic configuration of a shelter in accordance with a preferred embodiment of the reservoir ice storage method for maintaining the storage amount according to the present invention.

As shown in the figure, during the rainy season with a lot of rainfall or when a lot of rain falls intensively, the reservoir 100 stores and stores a sufficient amount of running water. Such a reservoir 100 may be applied in various sizes and shapes depending on the intended use.

Typically, the reservoir 100 is capable of storing water as much as the capacity of the reservoir 100 by sufficient precipitation from the summer season when the rainy season begins until the winter begins, to ensure a sufficient amount of water in preparation for the dry season something to do.

And, when the temperature is below freezing winter, the water surface of the reservoir 100 is frozen by the temperature to naturally form the ice layer 200. Since the ice layer 200 is formed on the water surface of the reservoir 100, when there is a severe wave on the water surface of the reservoir 100 by wind, or there is continuous inflow of water from the outside, and the reservoir 100 If the convection of the water stored in the interior is severe, there is a problem that the natural formation of the ice layer 200 is difficult.

In order to solve this, the float 120 is floated on the water surface of the reservoir 100. The float 120 is to be an ice core to facilitate the formation of the ice layer 200, and is formed to have a large surface area of a relatively light material so as to float on the surface of the reservoir 100. In this case, the float 120 may be fixed by a separate means such as a rope to prevent the floating down before the ice layer 200 is formed.

That is, when the temperature drops below zero to create an environment where ice can be frozen, the water floats at a predetermined position on the surface of the reservoir 100, and water of the reservoir 100 is sprayed toward the float 120. The ice layer 200 may be formed on the water surface of the reservoir 100 gradually from the surface of the float 120.

In addition, the float 120 may be prepared to initially be in contact with the ground surface to form the ice layer 200 from the surface and the adjacent edge.

On the other hand, although not shown in detail, without floating the float 120 on the water surface of the reservoir 100, it may be able to promote the freezing by supplying ice using a snow plow or ice maker, through which the ice layer more effectively It will also be possible to form 200.

Then, when water is sprayed toward the surface of the reservoir 140 and the reservoir 100 adjacent to the water surface to be described in detail below, rather than forming the ice layer 200 directly on the inner surface of the reservoir 100. From the surface of the reservoir 140 and the reservoir 100 adjacent to the water surface, the ice layer 200 is increased to the inside of the reservoir 100 using the water pump 300 which will be described in detail below. It will be able to more easily form the ice layer 200 on the water surface of the reservoir 100.

After the ice layer 200 is initially formed to have a predetermined thickness, external cold air that can freeze ice is insulated by the ice layer 200, and thus cannot be transferred to water under the ice layer 200. After the thickness of 200 is thickened to some extent, the thickening speed is significantly reduced. At this time, the thickness of the ice layer 200 is relatively thin as compared to the depth of the reservoir 100, the amount is also relatively small.

 As such, after the ice layer 200 is formed on the surface of the reservoir 100, the water below the ice layer 200 is pulled up by the water supply mechanism 300 to the upper side of the ice layer 200. The pumping device 300 is configured to pull water below the ice layer 200 upward above the ice layer 200, and selectively selects water below the ice layer 200 by a power unit using a pump or a motor. It is configured to be pulled up.

Referring to Figure 3 with respect to the pumping mechanism 300, the pumping mechanism 300 is a pumping pipe 310 and the injection means 320, the support member 330, the drive means 340 and the power supply means And 350.

The pumping pipe 310 is for guiding the water below the ice layer 200 above the ice layer 200. Even though the thickness of the ice becomes thick, the water pipe 310 moves the water below the ice layer 200 above the ice layer 200. It is formed to have a sufficient length to guide the.

If necessary, the pumping pipe 310 is installed on the bottom surface of the reservoir 100, the pumping mechanism 300 pulls up the water in the bottom of the reservoir 100 and at the same time the installation position of the pumping mechanism 300 It may be extended to the bottom surface of the reservoir 100 so that it can be fixed, in this case, the lower portion of the pump pipe 310 is configured so that both sides of the lower side of the reservoir 100 is allowed to enter.

In addition, the interior of the pumping pipe 310 will not be frozen because the water is continuously flowing, it may be formed of a heat insulating material so that the inside does not freeze even at sub-zero temperatures.

That is, when it stops raising the water at sub-zero temperature, the pumping pipe 310 and the injection nozzle of the pumping mechanism 300 may freeze, and thus the pumping apparatus 300 may not operate normally. If the temperature is expected to drop below zero, the pumping device 300 is continuously operated.

At this time, the water sprayed onto the ice layer 200 by the continuous operation of the pumping device 300 is drained through the already formed drainage, or as shown in Figure 2 the bypass pipe 400 in the middle of the pumping pipe 310 Along the back may be introduced into the ice layer 200 of the reservoir 100 again.

On the other hand, the support member 330 is formed on one side of the pump pipe (310). The support member 330 allows the pumping mechanism 300 to be fixed to the ice layer 200, and is formed in a plate shape in which a center thereof is penetrated by the pumping pipe 310.

The support member 330 is formed in a plate shape having a predetermined area to support the pumping mechanism 300 in contact with the top surface of the ice layer 200 when the ice layer 200 is frozen, and can float on water as needed. It is formed of a material such as a styrofoam, so that the ice layer 200 can be floating on the water surface of the reservoir 100 even when the ice layer 200 is not formed.

In addition, when the pumping device 300 is installed in the state where the ice layer 200 is already formed, the support member 330 pumps the ice layer 200 of the pumping device 300. In this case, the lower surface of the support member 330 is fixed to the pumping mechanism 300 while contacting the upper surface of the ice layer 200.

In addition, the driving means 340 and the injection means 320 is provided above the pump pipe 310. The driving means 340 is to provide power for raising the water below the ice layer 200, it is preferable that a pump driven by an electric motor generally used.

The upper end of the pump pipe 310 is provided with a spraying means 320 for spraying the water drawn up by the drive means 340 to both sides, the spraying means 320 is a state of particles Spray to ensure more effective freezing. Accordingly, water drawn up by the pumping mechanism 300 is sprayed above the ice layer 200 to freeze ice on the upper surface of the ice layer 200, thereby more effectively thickening the thickness of the ice layer 200. You can do it.

On the other hand, the driving means 340 is provided with a power supply means 350. The power supply means 350 transfers power for driving the driving means 340, and a wire generally used is used. The wire is to connect the power source provided on the outer surface of the reservoir 100 and the driving means 340 fixed to the ice layer 200 or the water surface of the reservoir 100, due to the growth of the ice layer 200 Even if it enters the inside of the ice layer 200 or located on the surface of the water, it may be desirable that the coating process is waterproof and heat-resistant to smoothly transfer power.

Of course, the driving means 340 may be operated by a solar rechargeable battery charged by solar heat, in addition to the electric power supply method by the wire, in this case, a separate wire connected to the ground will not be necessary.

On the other hand, the water pulled up by the pumping mechanism 300 above the ice layer 200 may not flow by the injection means 320 may flow to the upper surface of the already formed ice layer 200. Of course, at this time, since the heat of the water below the ice layer 200 and the geothermal heat transmitted further below this are blocked by the ice layer 200, the ice layer 200 may be gradually thickened by the sub-zero cold atmosphere.

The water drawn up by the pump 300 may be intensively sprayed in one direction, and may be formed to incline the top surface of the ice layer 200 through this method. When the top surface of the ice layer 200 is formed to be inclined, when the water is generated or introduced into the top surface of the ice layer 200 by solar radiation and rain water so that the ice layer 200 can be quickly drained along the inclined surface Will minimize the amount of melting.

In order to form an inclination on the upper surface of the ice layer 200 as described above, a plurality of pumping mechanisms 300 are installed at a position biased to one side from the entire surface of the reservoir 100 to form an ice layer 200 at one side of the reservoir 100. By thickening the thickness may naturally form the inclined surface of the upper surface of the ice layer 200.

If necessary, it may be possible to further form a drainage path through which water on the upper surface of the ice layer 200 can flow during the continuous formation of the ice layer 200.

Such a water pump 300 may be provided in plurality depending on the size of the reservoir 100, the more the water pump 300 is provided in the reservoir 100, the ice layer 200 of the reservoir ) Can be effectively thickened in a faster time.

The water drawn up above the ice layer 200 by the pumping device 300 is all frozen in the upper surface of the ice layer 200 by sub-zero temperatures, and thus the thickness of the ice layer 200 gradually increases. It becomes thick, so that a considerable amount of water stored in the reservoir 100 can be frozen.

The thickening of the ice layer 200 will be carried out continuously if the temperature is below zero and the ice layer 200 can be formed. If the temperature becomes an image, the ice layer 200 will no longer be thick. Since it is difficult to do so, it stops raising the water below the ice layer 200.

That is, since the water below the ice layer 200 has a temperature of 0 ° C. or more, when the water is sprayed by being lifted onto the ice layer 200, the ice layer 200 may be melted to stop the operation of the water pump 300. Done.

On the other hand, even during the day when the sun is strongly down the sun should stop raising the water below the ice layer 200, which will be described in more detail below.

Generally, the energy for melting ice is known to be 80cal / g, and the energy from solar radiation is provided to 2cal / cm 2 · min. Solar radiation is absorbed by about 50% of the atmosphere, and the remaining 50% is able to reach the Earth's surface, where ice again reflects 50-80%.

On the other hand, water reflects 8% of the solar radiation through the atmospheric layer and absorbs 92%. Consequently, the energy of solar radiation absorbed per unit area is 0.92cal / cm 2 · min. In other words, when cold radiation is received for 87 minutes in an area of 1 cm 2 in cold weather, it absorbs 80 cal / g of energy that can melt 1 g of ice.

Therefore, during the day, when the water under the ice layer 200 is pulled up and supplied to the upper surface of the ice layer 200, even if the temperature is below zero, the amount of melting of the ice is greater than that of freezing. Therefore, it is effective to stop the operation of raising the water using the pumping device 300 during the day when the sun radiation is strong.

However, if the temperature is below 15 degrees Celsius or less, the water can freeze only by heat conduction by air while receiving solar radiation, so that the water pump 300 is operated to pull water below the ice layer 200 to raise the water surface of the ice layer 200. It is possible to thicken the ice layer 200 by supplying.

When the ice layer 200 is formed at this temperature, the water below the ice layer 200 is supplied to the upper surface of the ice layer 200, and the water on the upper surface of the ice layer 200 is cooled again by the cold atmosphere. The ice layer 200 is continuously thickened by freezing. In particular, the ice layer 200 becomes thicker more effectively during nights where sub-zero temperatures continue.

Since the ice layer 200 formed as described above reflects or absorbs all of the solar radiation reaching the reservoir, the water of the reservoir 100 accommodated below the ice layer 200 does not receive the solar radiation and thus is not heated. In addition, until the ice layer 200 is completely melted, water generated while the ice layer 200 is melted continuously flows to prevent the water temperature of the reservoir 100 from rising.

Therefore, the thicker the ice layer 200 is, the longer it takes for the ice layer 200 to completely melt and the production of cold water by the ice layer 200 increases, thereby preventing the water temperature of the reservoir 100 from rising for a long time. The evaporation of water contained in the reservoir 100 is suppressed.

The amount of evaporation is expressed as E = (a + bU) (e _w -e _a ), where E is the amount of evaporation, a and b are constants, which vary slightly from region to region and season to season, and U is the wind speed over 1 m and e _w is the saturated vapor pressure of air on the water surface (or ice surface), and e _a is the vapor pressure over 1m. Since e _w changes with the temperature of the water surface (or ice surface) and e _a changes with the dew point temperature of the air, the amount of evaporation is proportional to the difference between the ice surface temperature and the air dew point temperature.

In this case, as the thickness of the ice layer 200 formed on the reservoir 100 becomes thicker, it takes longer for the ice layer 200 to melt all, while e _w has a small value, so that the reservoir 100 This minimizes the evaporation of water stored in).

On the other hand, there are a variety of factors as a factor for melting the ice layer 200. There are air conduction, sun radiation, condensed water, latent heat of condensation, and rain from the air as the temperature rises to the image.

First, when the ice layer 200 melts at the temperature of the image, the thickness of the ice layer 200 is 1m, the ice is 0 ° C, and the temperature is 30 ° C. ) Requires approximately 8000 cal of energy to melt.

Therefore, since B _a1 = 5.773 × 10 ⁻⁵ × 30 = 1.73 × 10 ⁻³ , the time taken for the ice layer to melt is about 8000 / (1.73 × 10 ⁻³ ) = 1284 hours, that is, about 54 days.

In order to melt the ice layer 200 by the solar radiation, the energy of the solar radiation absorbed by the ice per unit area (1 cm 2) is about 0.4 cal / cm 2 · min. Therefore, about 200 minutes is required to melt 1 g of ice. I get caught. That is, to melt the ice layer 200 having a thickness of 1 m with pure solar radiation energy, approximately 333 hours is consumed.

Of course, since the solar radiation does not occur during the night time, if this is taken into account when the ice layer 200 of 1m thickness is melted by the solar radiation energy is consumed twice the time, even if the solar radiation occurs, the weather or the morning evening sun Since the radiation is significantly different from that of noon, twice as much time is consumed, so that the ice layer 200 having a thickness of 1 m can be melted only after about 55 days.

And, when it rains, the upper surface of the ice layer 200 is melted by the rain water, in order to minimize the rain by forming the upper surface of the ice layer 200 is inclined as soon as the rain water comes into contact with the ice layer 200. Got to be.

As described above, the factors for melting the ice layer 200 vary depending on the situation, and thus it is difficult to calculate the exact value, but it takes about 27 days when roughly calculated. However, the spring temperature is rarely raised to 30 ℃, the thickness of the ice layer 200 can also be formed more than 1m. That is, when the ice layer is formed to a thickness of 2m or more, it can be seen that at least 2-3 months are consumed in order for the ice layer 200 to melt.

If the surface temperature is low, conversely, water in the air will enter the surface of the dew. The upper surface of the ice layer 200, that is, the ice surface has a lower vapor pressure than the water surface, so that the amount of evaporation is further reduced. Thus, when ice is on the surface of the water, the ice itself may suppress evaporation, but the cooled water temperature has an effect of suppressing evaporation.

Looking at this value, assuming that the wind speed is 2m / s, the evaporation amount is -0.48mm / h when the water temperature is 0 ℃. In other words, water vapor in the atmosphere is absorbed into the water rather than evaporating. And on the ice surface whose temperature is -1 degreeC, condensation is further accelerated by -0.80mm / h. However, when the water temperature is 25 ℃ evaporation occurs by 0.26mm / h.

As such, when the ice state or the water temperature is low, the amount of evaporation is greatly reduced. As a result, even if the ice layer 200 is formed in the reservoir 100 or the ice layer 200 melts, the water temperature of the reservoir 100 is reduced. Since the self is kept low for a certain period of time, it is possible to suppress the evaporation amount of the water stored in the reservoir 100 as much as possible after a certain time after all the ice is melted.

Since ice is 1/11 floating on water, the ice surface always floats on water. While floating on water, the sun's radiation prevents it from entering and absorbing water, which significantly slows the rate at which the ice melts and the water warms up. But once the ice has melted and there is no more ice on the surface, the amount of solar radiation on the surface is significantly increased and the rate of temperature rise is very fast.

In this case, in order to slow down the temperature increase rate of the reservoir 100 water, the shelter 140 is installed on one side of the reservoir 100. The ice storage 140 is to raise the water of the reservoir 100, or to store the water flowing into the reservoir 100 and freeze to accumulate, the ice layer formed on the water surface of the reservoir 100 When all are melted, it is formed to lower the water temperature of the reservoir 100 to suppress evaporation.

The shelter 140 may be formed anywhere in the underground space adjacent to the reservoir 100 or on the surface adjacent to the reservoir 100, and may be formed at a position higher than the surface of the reservoir 100. .

The location of the janggeok 140 such as this may be better if the area that can cover the sunlight and the weak wind, the area that is not exposed to precipitation. And, in a location exposed to sunlight or precipitation may be further provided with a separate shielding means for blocking it.

The ice storage of the shelter 140 may be made by cold air introduced from the outside, and if the idle power is used, more ice may be frozen. In addition, when the ice stored in the ice storage 140 melts, the flow of water is formed toward the reservoir 100 to completely melt the ice layer 200 of the reservoir 100 after the ice in the ice storage 140 Melted water is introduced into the reservoir 100 to suppress the rise in the water temperature of the reservoir 100.

On the other hand, the inside of the janggeok 140, the janggeokso pipe 500 that can pull up the water of the ice layer 200 is further formed. The shelter pipe (500) is one side is in communication with the lower portion of the reservoir 100, the other side is located inside the shelter 140, by lifting the water in the reservoir 100, the shelter ( By supplying to the 140 is to allow the ice layer 200 is further formed inside the ice storage 140.

The cup ice pipe 500 is preferably in communication with the bypass pipe 400, and sprays water to the cup ice 140 through the injection means 320 provided in the bypass pipe 400 Configured to do so.

In addition, the janggeokso 140 is formed by opening a portion so that the outside cold air flows, if necessary, the guide flow path for guiding the cold outside air flows into the janggeok 140 and the outside It may be configured to communicate.

Hereinafter, the operation of the ice storage method of the reservoir for maintaining the storage amount according to the present invention having the configuration as described above.

 Figure 4 is a flow chart showing step by step of a preferred embodiment of the reservoir ice storage method for maintaining the reservoir amount according to the present invention. Referring to Figures 1 to 4, before the temperature falls below zero, a plurality of pumping mechanism 300 in the reservoir 100 is installed in the reservoir (100). At this time, the pumping mechanism 300 may be installed to be floating on the water surface of the reservoir 100 by the support member 330, the pumping pipe 310 of the pumping mechanism 300 of the reservoir 100 It may be installed to be fixed to the ground.

When the temperature drops below 0 ° C, the water surface of the reservoir 100 begins to freeze. The surface of the reservoir 100 does not have much movement unless there is no wind or a large amount of flowing water from the outside, and the ice layer 200 is formed by the cold atmosphere.

However, if the wind is blowing a lot or the inflow of running water from the outside, the water surface of the reservoir 100 is shaken, it is difficult to freeze the water surface of the reservoir 100. At this time, by supplying a lot of snow and ice to the surface of the snow plow or ice maker to promote freezing. When there is not enough energy or facility to use a snow plow or ice maker, the float 120 having a predetermined area is floated on the surface of the reservoir 100, and the water of the reservoir 100 is placed on the upper surface of the float 120. When the sprayed on the ice layer 200 is formed around the surface of the float (120). [Preparation step (S100)]

On the other hand, when the shelter is installed on one side adjacent to the reservoir is to perform a somewhat different method than the above-described preparation step (S100).

That is, when an ice storage is installed on one side adjacent to the reservoir, when the temperature of the air drops below freezing, the ice layer is formed from the inside of the ice storage by raising water of the reservoir into the interior of the ice storage. At the same time as the ice layer of the ice sheet is formed, the ice layer is formed from the reservoir and the nearby surface.

For this purpose, water may be sprayed on the reservoir and the nearby surface, or may be induced to extend the ice layer of the shelter. In addition, a float floats on the edge of the reservoir so that an ice layer can be formed from the edge of the ice layer. That is, the ice layer extends from the ledge to the edge of the reservoir. [First preparation step (S110)].

Next, the water pump is installed from the edge of the reservoir where the ice layer is formed. The pumping mechanism is mounted so that the pumping tube penetrates the ice layer, and the pumping mechanism can be fixed by allowing the support member to be seated by the ice layer.

The ice layer is gradually formed by the pumping mechanism, and as the ice layer extends into the reservoir, other pumping apparatuses are continuously installed toward the reservoir to form an ice layer on the entire reservoir. 2 Preparation Steps (S120)]

After the ice layer 200 is formed, the pumping device 300 is operated, and the water below the ice layer 200 is pulled up above the ice layer 200 by the operation of the pumping device 300. Will be lost. [Pumping step (S200)]

The water drawn up by the pumping mechanism 300 above the ice layer 200 is sprayed in the state of small droplets by the spraying means 320 such as a nozzle from above the pumping mechanism 300. Therefore, the water sprayed by the pump 300 is lowered to the upper surface of the ice layer 200 in the same state as the ice ratio at sub-zero temperatures.

When water below the ice layer 200 is sprayed onto the upper surface of the ice layer 200 by the continuous operation of the pumping device 300, the continuous freezing operation occurs and the thickness of the ice layer 200 becomes gradually thicker.

When the ice layer 200 is sufficiently thick or has a very low temperature, the ice layer 200 may be supplied to the upper surface of the ice layer 200 without spraying water drawn up by the water pump 300. Water supplied to the upper surface of the ice layer 200 is frozen by heat conduction by cold atmosphere to thicken the upper surface of the ice layer 200. [Ice ice step (S300)]

On the other hand, when the solar radiation is strong during the daytime or the temperature is 0 ° C or more, the water supplied above the ice layer 200 cannot be frozen, so the water below the ice layer 200 is drawn to the water pump 300. The raising operation is stopped, and when the temperature drops below zero again, water is raised below the ice layer 200 and sprayed above the ice layer 200.

If the process is continuously repeated, the thickness of the ice layer 200 becomes gradually thicker, and as the thickness of the ice layer 200 becomes thicker, it is possible to prevent evaporation of water under the ice layer 200. . [Ice control step (S400)]

The ice layer 200 may remain unmelted until spring as well as in winter, thereby ensuring a reservoir of the reservoir 100 while the ice layer 200 is formed.

When the ice layer 200 formed thickly floats on the water in the reservoir 100, the water temperature is slowly increased because it reflects sunlight. In addition, the water generated by melting the ice layer 200 will be water at a relatively low temperature, not zero, and is mixed with the reservoir 100 to prevent a sudden rise in the water temperature of the reservoir 100, as well as lower the water temperature It is possible to slow down the evaporation rate of the reservoir water.

On the other hand, when the shelter is installed in the vicinity of the reservoir, the ice layer of the reservoir 100 is completely melted in April-May, so that only water remains in the reservoir 100. In this case, since the ice stored in the ice storage 140 is formed so as not to be blocked by direct sunlight as well as being affected by precipitation, the ice may be stored for longer than the ice layer 200, and the cold water generated when the stored ice is melted is It flows into the reservoir 100.

Therefore, even though all of the ice layer 200 melts and the water temperature of the reservoir 100 rises, the water flowing down from the shelter 140 is mixed with the water inside the reservoir 100 and thus the water temperature of the reservoir 100. It is to suppress the rise, thereby preventing the evaporation of the water stored in the reservoir 100. [Shaw step (S500)]

Through the evaporation of the water stored in the reservoir 100, it is possible to preserve the reservoir amount of the reservoir 100.

The scope of the present invention is not limited to the above-exemplified embodiments, and many other modifications based on the present invention will be possible to those skilled in the art within the above technical scope.

According to the present invention as described above, by thickening the ice layer of the reservoir, it is possible to maintain the ice layer for a long time, even if all of the ice layer of the reservoir is melted, the melted water flows into the reservoir, the ice is stored in the ice storage The melted and flowing water is introduced into the reservoir to prevent the temperature rise of the reservoir,

Therefore, it is possible to suppress evaporation of the water stored in the reservoir, thereby ensuring a low amount of water. It is possible to alleviate the shortage of water resources frequently generated during the spring dry season by securing a low amount of the reservoir, thereby making it possible to smoothly supply agricultural water, living water and power generation water.

In addition, the water of the reservoir can maintain a very cold temperature for a long time, thereby inhibiting the growth of phytoplankton in the water of the reservoir. Therefore, the water of the reservoir can prevent eutrophication by phytoplankton, thereby keeping the water quality clean.

Therefore, there is an effect of supplying high quality living water when the reservoir is used as a water source as well as preventing pollution of the reservoir.

In addition, even if the cost of thickening the ice layer of the reservoir is consumed a lot, it is possible to minimize the damage to agriculture and life caused by drought, thereby significantly reducing the cost of damage, when suppressing evaporation of water supply The amount of tap water can be saved, which is economical in terms of overall cost.

In addition, the ice layer formed on the reservoir is expanded and reproduced by the positive feedback, so that the duration of the ice layer on the upper surface of the reservoir becomes longer, thereby significantly reducing the amount of solar radiation energy absorbed by the reservoir water. In addition, there is a direct reflection of solar radiation.

Therefore, it may be expected that an effect that can partially solve the global warming phenomenon caused by solar radiation energy.

Claims (11)

A preparation step of installing a pumping device for raising water in the reservoir where water is stored; After the ice layer is formed on the surface of the reservoir water pumping step of operating the pumping device to raise the water under the ice layer above the ice layer; An ice-ice step of spraying the water drawn up by the pumping device onto the upper surface of the ice layer and freezing the water on the upper surface of the ice layer by cold air in a natural state; Ice storage method comprising the ice control step of adjusting the operation of the pumping device according to the weather conditions such as solar radiation and precipitation so that the ice layer continuously thickened. The method of claim 1, wherein in the preparation step, If the ice layer is not formed on the surface of the reservoir, floating ice having a certain surface area on the surface of the reservoir to promote freezing, characterized in that to promote freezing. The method of claim 1, wherein in the preparation step, If the ice layer is not formed on the water surface of the reservoir, ice storage method characterized in that to supply ice to the ice maker or snow plow on the water surface of the reservoir to promote freezing. The method of claim 1, wherein in the preparation step, Ice storage method of the reservoir, characterized in that the ice storage is further formed on one side of the reservoir is a space that can be frozen and stored in the cold air by pulling up the water of the reservoir. The method of claim 4, wherein It is formed on the edge of the reservoir, formed in a position higher than the water surface of the reservoir, the ice storage method of the reservoir, characterized in that it further provided with a shielding member to prevent sunlight and rain. The method of claim 4, wherein in the icing step, An ice storage method for a reservoir, characterized in that the spraying means for spraying the water drawn up by the pumping mechanism in the form of small particles. The method of claim 4, wherein in the ice control step, Ice storage method of the reservoir, characterized in that when the temperature rises or the rain stops the operation of the pump. The method of claim 4, wherein After all of the ice layer is melted ice storage method of the reservoir is characterized in that the ice stored in the ice sheet melts flowing into the reservoir to lower the water temperature of the reservoir water to suppress evaporation is further carried out. A first preparation step of injecting water into the surface of the reservoir and the surface of the reservoir outside the reservoir formed on one side of the reservoir where water is stored to freeze; A second preparation step of installing a pumping device in the ice layer formed by the first preparing step, and continuously installing the pumping device as freezing proceeds to the inside of the reservoir; After the ice layer is formed on the surface of the reservoir water pumping step of operating the pumping device to raise the water under the ice layer above the ice layer; An ice-ice step of spraying the water drawn up by the pumping device onto the upper surface of the ice layer and freezing the water on the upper surface of the ice layer by cold air in a natural state; Ice storage method comprising the ice control step of adjusting the operation of the pumping device according to the weather conditions such as solar radiation and precipitation so that the ice layer continuously thickened. The method of claim 9, wherein in the first preparation step, Ice storage method of the reservoir, characterized in that the water is supplied to the inside of the janggeokgo by the janggeokso pipe separately provided in the janggeokgo occurs. The method of claim 9, wherein in the ice control step, And the pumping mechanism is continuously operated to bypass the water of the reservoir by a bypass pipe connected to the pumping mechanism and connected to a lower portion of the reservoir.

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