KR101788547B1 - Operation and maintenance system of fountain - Google Patents

Abstract

The present invention provides a fountain operation management system. The fountain operation management system includes a fraction storage unit 100 storing stored water, a fraction generating unit 200 connected to the fraction storage unit and performing a presentation using the stored water, A water supply unit 300 for supplying purified water to the fractional water tank through the water supply unit; A drainage unit 400 draining water stored in the fraction receiving unit; A washing unit 500 installed in the fraction receiving unit to wash the stored water; A meteorological measurement unit 600 for measuring a meteorological condition; And washing the water stored in the wastewater receiving portion using the washing portion in accordance with the gas phase state to be measured, draining the washed water using the drain portion, and discharging the washed water to the water outlet portion And a control unit 700 for supplying water to the gutter to replace the water stored in the water receiving unit or replacing water stored in the water receiving unit using rainwater to maintain a predetermined water level.

Description

{OPERATION AND MAINTENANCE SYSTEM OF FOUNTAIN}

The present invention relates to a fountain operation management system, and more particularly, to a fountain operation management system that controls a fountain operation according to a weather condition and controls the use of a constant used in a fountain depending on the amount of water to reduce the use of a constant, And more particularly, to a fountain operation management system that reflects weather conditions that can clean and sterilize rainwater used in real-time fractions when used.

Recently, fountains in parks and so on have been kept in a low rate due to the necessity of continuous management by administrators due to sediment and pollution sources.

And, as the fountain is recognized as a space where children can play with water until spring, summer, and autumn, the operation rate is rising, but the problem is exposed to fundamental operation and management.

Particularly, there is a problem that it is difficult to maintain the safety of water because the operation ratio is increased.

In addition, as the operation rate of the fountain increases, the cost of maintenance (electricity, water, sewerage, sterilization) increases, resulting in increased energy consumption and increased maintenance costs due to the operation ratio.

Generally, the fountain block installed on the outdoors is composed of a jetting device in which a water supply hose and a jet are connected to both sides of the drive pump.

This is widely used in the summer season, but it has the effect of making the surrounding landscape more beautiful and providing coolness in hot weather.

In the summer season, it is unnecessary to use the fountain in the rainy season such as sudden rainfall or the rainy season. Therefore, the use of the fountain is limited. For this purpose, the manager who manages the fountain conventionally detects the rainfall amount and restricts the operation of the fountain by hand.

However, it was difficult to judge whether the rain that suddenly falls during the summer season is a one-time rain or a rain that falls for a long time.

In other words, it is very inconvenient and cumbersome for the manager to control the use of the fountain at the time of rainy weather, and it is very difficult to judge whether the amount of rainfall is large. Therefore, the administrator has to leave the fountain for a certain period of time. This causes waste of electric power and wasted manpower due to unnecessary use of the fountain.

In addition, when the storm is used as the spray, there are various foreign substances and pathogens.

A prior art related to the present invention is Korean Registered Patent Registration No. 10-1230077, which discloses a technique relating to rainwater recirculation fountains using solar energy.

It is an object of the present invention to provide a method and apparatus for controlling a fractional operation according to a gas phase and controlling the use of constants used for fractions according to the amount of water to reduce the use of constants, The present invention provides a fountain operation management system capable of cleaning and sterilizing rainwater.

In a preferred embodiment, the present invention provides a fountain operation management system.

The fountain operation management system includes a fraction storage unit 100 storing stored water, a fraction generating unit 200 connected to the fraction storage unit and performing a presentation using the stored water, A water supply unit 300 for supplying purified water to the fractional water tank through the water supply unit; A drainage unit 400 draining water stored in the fraction receiving unit; A washing unit 500 installed in the fraction receiving unit to wash the stored water; A meteorological measurement unit 600 for measuring a meteorological condition; And washing the water stored in the wastewater receiving portion using the washing portion in accordance with the gas phase state to be measured, draining the washed water using the drain portion, and discharging the washed water to the water outlet portion And a control unit 700 for supplying water to the gutter to replace the water stored in the water receiving unit or replacing water stored in the water receiving unit using rainwater to maintain a predetermined water level.

Wherein the gas phase measurement unit includes a rainfall sensor that measures a rainfall amount and transmits the rainfall amount to the control unit, and a temperature sensor that measures a temperature and transmits the measured temperature to the control unit,

The control unit drains water stored in the fraction receiving unit using the drain unit when the measured temperature reaches a predetermined reference temperature and supplies the purified water to the fraction receiving unit using the water supply unit To maintain the set water level,

When the measured amount of rainfall to be transmitted reaches the set reference rainfall amount, it is preferable to clean the stored water using the washing unit, and to maintain the predetermined water level as the rainwater is stored in the fraction receiving unit.

The washing unit is driven by receiving a control signal from the control unit and is disposed in the vicinity of the inner bottom of the fraction receiving unit to supply air to the stored water in response to inflow of external pressure air, And a rising pressure air supply unit.

The gas-phase measuring unit includes an air-flow sensor for measuring the air volume,

Preferably, when the measured air flow reaches a set reference air flow rate, the control unit variably adjusts a directed state through the fractional flow direction.

Wherein the fraction generating unit includes an illuminance sensor for measuring the illuminance and transmitting the illuminance to the control unit,

In the control section, a reference illuminance corresponding to 24 hours is set,

The control unit preferably controls the driving of the illumination lamp included in the fractional directing unit so that the measured illuminance satisfies the reference illuminance.

A water quality sensor for measuring the dissolved oxygen amount of the stored water is installed in the fraction receiving portion,

Wherein the control unit cleans the water stored in the fraction receiving unit using the cleaning unit so that the measured dissolved oxygen amount reaches a predetermined reference dissolved oxygen amount and drains the cleaned water using the drainage unit, It is preferable to control the supply of the washed water to the fractionating water tank by using the supply unit.

Wherein the pressure air supply unit includes an air supply unit for supplying pressure air under the control of the control unit and a cleaning pipe disposed in the vicinity of the inner bottom of the fraction receiving unit for discharging the pressure air to the outside,

Preferably, the cleaning tube is provided with a plurality of spray holes through which the pressure air is injected.

It is preferable that the plurality of injection holes are formed to have different hole sizes from each other.

Wherein the rotary shaft is connected to a motor shaft of a rotary motor rotated under the control of the control unit,

Preferably, the control unit controls the rotation state of the cleaning pipe by driving the rotation motor at a rotation speed set to be proportional to the measured rotation speed of the rotation shaft.

It is preferable that a plurality of blades are formed on the outer circumference of the washing tube.

It is preferable that a sterilizing light irradiator for receiving the control signal from the control unit and irradiating the stored water with sterilizing light is provided in the fraction receiving portion.

The present invention controls fractional operation according to the weather condition and controls the use of constants used for fractions according to the amount of rain to reduce the use of constants. Cleaning and sterilization can be performed.

1 is a view showing a configuration of a fountain operation management system according to the present invention.
2 is a view showing an example of a washing unit according to the present invention.
3 is a view showing another example of the washing unit according to the present invention.
4 is a view showing the vibration structure of the fraction receiving part according to the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings so that those skilled in the art can easily carry out the present invention.

The present invention may be embodied in many different forms and is not limited to the embodiments described herein.

In order to clearly illustrate the present invention, parts not related to the description are omitted, and the same or similar components are denoted by the same reference numerals throughout the specification.

Hereinafter, the term "an upper (or lower)" or a "top (or lower)" of the substrate means that any structure is disposed or arranged in any manner, as long as any structure is provided or disposed in contact with the upper surface .

Furthermore, the present invention is not limited to a configuration that does not include any other configuration between the substrate and any configuration provided or disposed on (or under) the substrate.

Hereinafter, a fountain operation management system according to the present invention will be described with reference to the accompanying drawings.

1 is a view showing a configuration of a fountain operation management system according to the present invention.

1, a fountain operation management system according to the present invention includes a fountain 100, a fraud extension 200, a water supply unit 300, a drainage unit 400, a cleaning unit 500, A gas phase measurement unit 600, and a control unit 700. [

Each of the above configurations will be described.

A set amount of water is received in the fraction receiving portion 100.

The fraction generating part 200 includes a plurality of lighting modules 210 and a driver 220.

The plurality of lighting modules 210 of the fractional extension 200 are disposed above the fractional catcher 100. Of course, it is waterproof.

The driver 220 receives the control signal from the control unit 700 and emits light through the lighting modules 210. The driver 220 drives the lighting modules to reach a directing condition such as an illuminance and a divergence time .

Accordingly, the fraction generating part 200 according to the present invention is connected to the fraction receiving part 100, and can perform the production using the stored water.

The water supply unit 300 according to the present invention serves to supply the washed water from the water source to the water collection unit 100.

The water supply unit 300 includes a supply pipe 320 and a water supply source 310.

The supply pipe 320 is connected to the inside of the fraction receiving part 100 at one side of the fraction receiving part 100.

A valve (not shown) is installed in the supply pipe 320, and the valve is opened and closed in accordance with a control signal of the controller 700 to control the flow of water.

The water source 310 supplies purified water, which is constant, to the fraction receiving unit 100 through the supply pipe 320.

The drainage unit 400 according to the present invention includes a drainage pipe 410 connected to the interior of the fountain receiving unit 100 at one side of the fountain receiving unit 100 and a drain pipe 410 installed at the drainage pipe 410 Off valve 420 that is opened and closed by a control signal of the control unit 700. [

The drainage unit 400 drains the water stored in the fraction storage unit 100.

The washing unit 500 according to the present invention is installed in the fountain receiving unit 100 and serves to wash the stored water.

The washing unit 500 is driven in response to a control signal from the control unit 700 and is disposed in the vicinity of the inner bottom of the fraction receiving unit 100 to supply air to the stored water in response to external pressure air inflow And a pressure air supply unit 520 for floating the floats contained in the stored water.

In addition, in the present invention, the gas phase measurement unit 600 serves to measure the gas phase state.

The gas phase measurement unit 600 may include a rainfall sensor 610 for measuring a rainfall amount, a temperature sensor 620 for measuring a temperature, an air flow rate sensor 630 for measuring an air flow rate, and the like.

The gas phase state according to the present invention is information such as the rainfall amount, the air temperature, and the air flow amount measured as described above.

The control unit 700 according to the present invention can clean the water stored in the water collection unit 100 using the cleaning unit 500 according to the wakeup condition measured as described above, And the purified water is supplied to the water receiving unit 100 by using the water supply unit 300 to replace the water stored in the water receiving unit 100, The water stored in the fraction receiving portion 100 may be replaced using rainwater to maintain a predetermined water level.

A water level sensor 910 for measuring the water level and transmitting the water level to the control unit 700 is installed in the water receiving unit 100.

A temperature sensor 820 for measuring the temperature of water and a water quality sensor (not shown) for measuring the dissolved oxygen amount are provided in the fraction receiving portion 100.

Above, each configuration of the fountain operation management system of the present invention has been described above.

Next, the gas phase measurement unit 600 according to the present invention will be described in detail.

The gas phase measurement unit 600 according to the present invention includes a rainfall sensor 610 for measuring the amount of rainfall and transmitting it to the controller 700 and a temperature sensor 620 for measuring the temperature and transmitting the measured temperature to the controller 700 .

A water level sensor 910 for sensing the water level and transmitting the water level to the control unit 700 is installed in the water collection unit 100.

When the measured rainfall amount measured and transmitted from the rainfall sensor 610 reaches the set reference rainfall amount, the control unit 700 cleans the stored water using the washing unit 500, So that the water level can be controlled to be maintained as it is stored in the water receiving unit 100.

Here, the control unit 700 uses the drainage unit 400 to clean the rainwater stored in the fraction storage unit 100 and to drain the drainage water using the drainage unit 400.

For example, it may be a state where the rainfall falls continuously as the reference rainfall amount is reached.

The rainwater may be gradually stored in the fraction receiving part 100, and the water level may be increased.

Therefore, the control unit 700 can continuously drain the rainwater using the drainage unit 400 so that the water level of the wastewater receiving unit 100 is maintained at the set water level.

At this time, the supply of the constant water through the constant supply unit 300 is blocked.

In addition, by using the cleaning unit 500, the floating matters contained in the rainwater can be forcedly floated, and can be included in the flow of the rainwater to be drained.

Therefore, there is an advantage that it can be used as a fountain at the same time as washing by using rainwater without using a separate constant.

Here, the construction and operation of the washing unit 500 will be described later.

Meanwhile, the controller 700 may receive the measured temperature measured from the temperature sensor 620.

In the control unit 700, a reference temperature corresponding to the season is set. The reference air temperature may be a temperature corresponding to spring, summer, autumn and winter.

The control unit 700 controls the operation of the water supply unit 300, the cleaning unit 500, and the drainage unit 400, which correspond to the reference air temperature according to the respective seasons, Can be controlled.

For example, in the case of a winter temperature, the operation of the water supply unit 300, the cleaning unit 500, and the drainage unit 400 may be stopped.

However, when the operations of the water supply unit 300, the cleaning unit 500, and the drainage unit 400 are stopped, the controller 700 drives the lighting modules 210 of the fraction generating unit, , It can be used as lighting for fractional operation.

When the measured temperature measured by the temperature sensor 820 reaches a preset reference temperature, the control unit 700 controls the water stored in the fraction storage unit 100 using the drainage unit 400 And the purified water can be supplied to the fraction receiving unit 100 using the water supply unit 300 to maintain the set water level.

The temperature sensor 820 may measure the temperature of the water in the fraction receiving part 100 and transmit the measured temperature to the control part 700.

In the control unit 700, a reference temperature is set. The reference temperature may be a temperature at which contamination occurs due to a shortage of dissolved oxygen in water.

When the temperature of the water reaches the reference temperature, the control unit 700 drains the stored water using the drain unit 400.

At the same time, the water supply unit 300 is used to supply the washed water to the fractional water collecting unit 100 so that the water level in the fractional water receiving unit 100 reaches the predetermined water level.

Accordingly, as the water temperature in the fraction receiving portion 100 rises, it is possible to solve the problem that the scum is generated and contaminated.

Meanwhile, the gas-phase measuring unit 600 according to the present invention includes a flow rate sensor 630 for measuring the flow rate

The air flow rate sensor 630 measures the air flow rate and transmits the air flow rate to the controller 700.

The reference air volume is set in the controller 700. The reference air volume may be a value at which a problem may be caused in rendering the fraction.

When the measured air volume reaches the set reference air volume, the controller 700 variably adjusts the directed state through the fractional continuous channel 200, and stops driving the driver of the fractional continuous channel 200 good.

Accordingly, it is possible to stop the operation of the fountain at a time when the wind is severely blowing, thereby preventing unnecessary energy wastage.

In addition, the gas-phase measuring unit 600 according to the present invention may include an illuminance sensor (not shown) for measuring the illuminance and transmitting the measured illuminance to the controller 700

Here, it is preferable that the control unit 700 is set to a reference illuminance corresponding to 24 hours.

The control unit 700 may control the driving of the lighting modules 210 included in the fractional directing unit 200 so that the measured illuminance satisfies the reference illuminance.

Accordingly, the illuminance of the lighting modules 210 can be variably controlled according to the time of day, so that the illuminance during daytime and nighttime can be variably controlled.

In addition, a water quality sensor (not shown) for measuring the dissolved oxygen amount of the stored water may be installed in the fraction receiving part 100 according to the present invention.

The control unit 700 can wash the water stored in the fraction storage unit 100 using the cleaning unit 500 so that the measured dissolved oxygen amount reaches a predetermined reference dissolved oxygen amount.

At the same time, it is possible to drain the washed water by using the drainage unit 400, and to supply the washed water to the water receiving unit 100 using the water supply unit 300.

The water level of the molten water and the fractional water receiving portion 100 can be controlled to reach the water level set equal to the above-described level.

Meanwhile, a sterilizing light irradiator 900 may be installed in the fraction receiving part 100 to receive a control signal from the controller 700 to irradiate sterilized light to the stored water.

The sterilizing light irradiator 900 is driven under the control of the controller 700. When the controller 700 determines that the amount of dissolved oxygen measured by the water quality sensor is less than a preset reference dissolved oxygen amount, So that sterilizing light can be irradiated to the water in the fraction receiving portion 100. [

In addition, although not shown in the drawing, the sterilizing light irradiator 900 includes a lamp for irradiating sterilizing light and a rotator for rotating the lamp, and the rotator can rotate the lamp under the control of the controller 700 .

The rotator 700 has a shaft formed at the center of the bottom of the fraction receiving part 100 and a motor for rotating the shaft.

The shaft is connected to the lower end of the lamp and, when the shaft is rotated, the lamp may be rotated 360 degrees in a horizontal state.

In addition, the shaft is provided with a cylinder having a cylinder shaft that can be expanded or retracted, and the lifting and lowering position of the lamp may be adjusted by lifting and lowering the cylinder shaft in accordance with expansion and contraction. The cylinder can be stretched and contracted such that the cylinder axis is lifted and lowered under the control of the controller 700.

The following describes the implementation of the cleaning part according to the present invention.

2 is a view showing an example of a washing unit according to the present invention.

Referring to FIG. 2, the cleaning portion 500 according to the present invention includes a pressure air supply portion.

The pressure air supply unit includes an air supply unit 520 for supplying pressure air under the control of the control unit 700, and an air supply unit 520 disposed near the inner bottom of the water collection unit 100, And a washing pipe 510 for washing the washing water.

The pressure air supply 520 has a pressure pipe 521 for delivering pressure air to the cleaning pipe 510.

The cleaning pipe 510 may be formed of stainless steel to prevent rusting.

Here, a plurality of spray holes 511 through which the pressure air is sprayed may be formed in the washing pipe 510.

The plurality of injection holes 511 may be formed to have different hole sizes from one another.

3 is a view showing another example of the washing unit according to the present invention.

3, the rotation shaft 510a is formed so that both ends of the cleaning pipe 510 according to the present invention are rotatably supported inside the fraction receiving portion 100. [

The rotary shaft 510a is rotatably supported on one side wall of the fraction receiving part 100 and connected to a motor shaft (not shown) of a rotary motor 530 installed on one side wall of the fraction receiving part 100. [

The rotation shaft 510a at the other end is rotatably connected to the end of the pressure pipe 521 disposed at the other side wall of the fraction receiving part 100. [ The other end of the rotary shaft 510a may be connected to the pressure pipe 521 to supply the pressure air to the inside of the cleaning pipe 510.

Accordingly, the control unit 700 drives the rotation motor 530 to rotate the rotation shaft 510a, thereby rotating the cleaning pipe 510.

The control unit 700 controls the rotation speed of the cleaning pipe 510 by driving the rotation motor 530 at a rotation speed set to be proportional to the measured temperature, can do.

Here, the temperature is the internal water temperature of the fraction receiving portion.

Accordingly, in the present invention, when the temperature of the water in the water tank rises to a predetermined level or more, the float can be efficiently discharged using the drainage unit 400 by increasing the degree of floatation by rotating the washing pipe 510.

In addition, the control unit 700 may rotate the rotation direction of the rotary shaft repeatedly along the forward and reverse directions to induce the floating body to be more efficiently floated.

On the other hand, although not shown in the drawing, a plurality of blades may be formed on the outer circumference of the cleaning pipe 510.

Accordingly, when the cleaning pipe 510 is rotated, foreign matter contained in the water stored in the fraction receiving portion by the plurality of blades may be floated more efficiently.

In addition, the blades may be coated with a photocatalyst so that they are exposed to water to achieve a germicidal effect.

4 is a view showing the vibration structure of the fraction receiving part according to the present invention.

In particular, referring to FIG. 4, in the present invention, vibrations may be applied to the water receiving portion 100 itself to forcibly activate the floating of foreign matter contained in the rainwater stored in the water receiving portion 100.

In other words, the outside water receiving portion 950 is disposed on the outer side of the fraction receiving portion 100 according to the present invention.

That is, the fraction receiving portion 100 is disposed inside the outer receiving portion 950.

The inner periphery of the outer receiving portion 950 and the outer periphery of the fraction receiving portion 100 may be connected by a plurality of elastic springs 951.

In addition, cylinders 970 are disposed at the inner edge of the inner periphery of the outer receiving portion 950. The cylinders 970 have a stretchable shaft 971.

The shafts 971 of each of the cylinders 970 are connected to the outer circumferential edge portion of the fraction receiving portion 100 and are connected by forming a hinge H. [

Here, the cylinders 970 can repeat the expansion and contraction operation of the corresponding shaft 971 in response to a control signal from the control unit 520.

Therefore, in accordance with the repetition of the expansion and contraction of the shaft 971 of the cylinders 970, vibration can be applied to the fraction receiving portion 100.

The outer receiving portion 950 may include a drainage passage 960 for discharging water, which may be formed between the outer receiving portion 950 and the fraction receiving portion 100, to the outside. The drainage passage 960 is provided with a pump 961 for discharging moisture to the outside. The pump 961 is driven under the control of the controller 700.

In addition, a water quality sensor (not shown) for measuring the dissolved oxygen amount is installed in the fraction receiving portion 100.

Dissolved oxygen amount ranges are set in the controller 700 and the expansion speeds of the shafts 971 of the cylinders 970 are set to be different from each other depending on the dissolved oxygen amount ranges.

Accordingly, when receiving the measured dissolved oxygen amount from the water quality sensor, the controller 700 can control the expansion and contraction of each axis of the cylinders 970 so as to achieve the expansion and contraction speed corresponding to the measured dissolved oxygen amount.

As described above, according to the embodiment of the present invention, the rainwater and the rainwater are stored in the fountain receiving unit, thereby reducing the water resources of the water-deficient country. In addition, There is an advantage that the amount of dissolved oxygen (DO) can be increased by injecting air and the source of the bottom water tank can be removed.

In addition, the embodiment according to the present invention uses the meteorological measuring unit to increase the temperature of water of the fountain due to evaporation of the water gradually, and it increases in the organic matter in the water, so that it is polluted by the smell and the occurrence of the green tide by the decrease of dissolved oxygen and eutrophication, It has the advantage of solving the problem of causing pathogens (Escherichia coli, Salmonella) in water.

Accordingly, the present invention can further prevent water temperature rise and sterilize by supplying fresh water, thereby securing a clean water space.

Further, the embodiment of the present invention is advantageous in that, when the continuous precipitation occurs, the automatic opening and washing of the bottom sedimentation hole automatic valve is performed, thereby securing clean water space without water supply and saving water resources.

Further, in the embodiment of the present invention, when a strong wind is generated by using a weather sensor, it is possible to actively control the operation of the fountain block to prevent waste of unnecessary energy, to use a fountain lighting It has the advantage of being able to access to the four seasonal water space because the lighting can be produced.

As described above,

It should be understood that various modifications may be made without departing from the scope of the present invention.

Therefore, the scope of the present invention should not be limited to the above-described embodiments, but should be determined by the scope of the appended claims and equivalents thereof.

It is to be understood that the foregoing embodiments are illustrative and not restrictive in all respects and that the scope of the present invention is indicated by the appended claims rather than the foregoing description, It is intended that all changes and modifications derived from the equivalent concept be included within the scope of the present invention.

100:
200: Fractional chapter
300:
400:
500: Cleaning section
600: Weather measurement unit
700:

Claims (10)

A fountain receiving part for storing water to be stored;
A fraction generating section connected to the fraction receiving section and performing the presentation using the stored water;
A water supply unit for supplying water, which has been washed through the water source, to the fraction water tank;
A drainage unit for draining the water stored in the fraction receiving unit;
A washing unit installed in the fraction receiving unit to wash the stored water;
A meteorological measurement unit for measuring a meteorological condition; And
The water stored in the wastewater receiving portion is washed using the washing portion according to the measured wakeup condition, the wastewater is drained using the wastewater, and the wastewater is drained using the water supplying portion, And a control unit for replacing the water stored in the water receiving unit by water or replacing the water stored in the water receiving unit using rainwater to maintain a predetermined water level,
The gas-
A rainfall sensor for measuring a rainfall amount and transmitting the rainfall amount to the control unit,
And a temperature sensor for measuring the temperature and transmitting the measured temperature to the controller,
Wherein,
Wherein when the measured temperature reaches a preset reference temperature, the water stored in the fraction receiving portion is drained using the drainage portion, the purified water is supplied to the fraction receiving portion using the water supply portion, Keep the water level,
The control unit controls the washing unit to wash the stored water using the washing unit when the measured amount of rainfall reaches the set reference rainfall amount and to maintain the predetermined water level as the rainwater is stored in the water receiving unit,
The cleaning unit includes:
And a control unit for controlling the supply of air to the stored water in response to the inflow of external pressure air, A supply portion,
The pressure air supply unit includes:
An air supply unit for supplying pressure air under the control of the control unit,
And a cleaning pipe disposed in the vicinity of an inner bottom of the fraction receiving portion and supplied with the compressed air and injecting the compressed air to the outside,
In the cleaning pipe,
A plurality of injection holes through which the pressure air is injected are formed,
Wherein the plurality of injection holes are formed to have different hole sizes from each other,
The rotary shaft is rotatably supported at both ends of the washing tube in the water receiving portion,
The rotary shaft formed at one end of the washing pipe is rotatably supported on one side wall of the fraction receiving portion and connected to a motor shaft of a rotary motor installed on a side wall of the fraction receiving portion,
Wherein the rotary shaft formed at the other end of the washing pipe is rotatably connected to an end portion of a pressure pipe disposed on the other side wall of the fraction receiving portion,
And a flow path connected to the pressure tube and supplying pressure air to the inside of the washing tube is formed in a rotary shaft formed at the other end of the washing tube,
The control unit drives the rotation motor to rotate the rotation shaft formed at one end of the cleaning pipe to rotate the cleaning pipe,
Wherein the control unit variably controls the rotation speed of the cleaning pipe by driving the rotation motor at a rotation speed set to be proportional to the measured temperature, the rotation speed of the rotation shaft formed at one end of the cleaning pipe,
Wherein the control unit repeatedly rotates the rotating direction of the rotating shaft formed at one end of the washing tube along the normal direction,
Wherein a plurality of blades coated with a photocatalyst are formed on an outer periphery of the washing pipe.
delete delete The method according to claim 1,
The gas-
And an air flow rate sensor for measuring the air flow rate,
Wherein,
And when the measured air flow reaches a set reference air flow rate, the direction of the discharged water flow is variably controlled through the fractional flow direction.
The method according to claim 1,
The fractional-
And an illuminance sensor that measures the illuminance and transmits the measured illuminance to the control unit,
In the control section, a reference illuminance corresponding to 24 hours is set,
Wherein,
And controls the driving of the illumination lamp included in the fractional discharge section so that the measured illuminance satisfies the reference illuminance.
The method according to claim 1,
In the fraction holding portion,
And a water quality sensor for measuring the dissolved oxygen amount of the stored water.
The method according to claim 6,
Wherein,
Washing the water stored in the fraction receiving portion using the washing portion so that the measured dissolved oxygen amount reaches a preset reference dissolved oxygen amount, draining the washed water using the drain portion, and using the constant supplying portion And controls the washed water to be supplied to the fractionating water tank.
delete delete delete

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