KR102222692B1 - Combined Control Mode System of Seawater Desalination Unit and Rainwater Purification Unit - Google Patents

Abstract

The present invention provides a complex control mode system controlled by a control unit (600) having a computing means. The complex control mode system of a seawater desalination device and a rainwater purification device comprises: a seawater desalination device (100) desalinated by inflow of seawater; a rainwater purification device (200) purifying stored rainwater; a rainwater storage unit (300) supplying stored rainwater to the rainwater purification device (200) and having a rainwater level sensor (310) on one side; a drinking water storage unit (400) storing drinking water desalinated in the seawater desalination device (100) and the drinking water purified by the rainwater purification device (200) and having a drinking water level sensor (410) on one side; a concentrated seawater storage unit (500) in which the concentrated seawater discharged from the seawater desalination device (100) is stored; and a control unit (600) receiving measured values of the rainwater level sensor (310) and the drinking water level sensor (410), wherein the control unit controls the seawater desalination device and the storm water purification device in any one mode of a normal season mode, a rainy season mode, or a dry season mode.

Description

Combined Control Mode System of Seawater Desalination Unit and Rainwater Purification Unit}

The present invention relates to a complex control mode system of a seawater desalination apparatus and a storm water purification apparatus.

Korea is a water shortage country established by the UN. Korea's annual average rainfall is 1273mm, which is much more than the world average of 973mm, but its population density is very high, making it a water shortage country, and there is no way to effectively and economically solve the problem of living water and drinking water, especially in islands.

The reverse osmosis type seawater desalination system applied in the present invention is only about 30% of the same freshwater output compared to the conventional evaporative seawater desalination system, and above all, it can be miniaturized, so it is applied to the solution of drinking water in islands. It has the advantage of having sex.

However, there is a problem in that there is instability in power supply and demand due to long-distance transmission, which is peculiar to coastal and island regions, and the cost of power required is considerably burdened when the seawater desalination system is dedicated to drinking water.

Accordingly, the present invention aims to solve the above problem by efficiently operating each device according to the normal season, the rainy season, and the dry season while using the seawater desalination device and the excellent water purification device together.

(Document 1) Korean Registered Patent Publication No. 10-1702850 (2017.01.31)

The complex control mode system of the seawater desalination apparatus and the storm water purification apparatus according to the present invention has the following challenges.

First, it tries to make the most of rainwater resources (excellent) with low power consumption.

Second, for the shortage of drinking water that may occur during the dry season, seawater is intended to be desalized and used.

Third, the required power is to be supplied independently using solar power generation.

Fourth, condensed seawater, a by-product of the seawater desalination system, should be used commercially.

The problem of the present invention is not limited to those mentioned above, and other problems that are not mentioned will be clearly understood by those skilled in the art from the following description.

The present invention is a complex control mode system controlled by a control unit having a computing means, the seawater desalination apparatus in which seawater is introduced and desalized; A rainwater purification device that purifies stored rainwater; A rainwater storage unit supplying the stored rainwater to the rainwater purification device, and having a rainwater level sensor on one side thereof; A drinking water storage unit storing drinking water desalted by the seawater desalination device and drinking water purified by the excellent water purification device, and having a drinking water level sensor on one side thereof; And a concentrated seawater storage unit for storing concentrated seawater discharged from the seawater desalination device, wherein the control unit receiving the measured values of the storm water level sensor and the drinking water level sensor sets the seawater desalination device and the storm water purification device in a normal season mode and a rainy season. It can be implemented as a complex control mode system of a seawater desalination apparatus and a storm water purification apparatus, characterized in that the control in either mode or the dry season mode.

In the present invention, the normal season mode starts when the measured value of the storm water level sensor falls within the preset low water level range, and the normal season mode is set when the measured value of the storm water level sensor falls within the preset maximum water level range. It can be ended.

In the present invention, in the normal water season mode, when the measured value of the drinking water level sensor is less than the preset low water level range, the excellent water purifying device is started, and when the measured value of the drinking water level sensor falls within the preset high water level range, the excellent water purifying device is It can be deactivated.

In the present invention, in the rainy season mode, the rainy season mode starts when the measured value of the storm water level sensor falls within the preset maximum water level range, and the rainy season mode can be terminated when the measured value of the storm water level sensor is less than the preset medium water level range. have.

In the present invention, in the rainy season mode state, when the measured value of the drinking water level sensor is less than the preset medium water level range, the excellent water purification device is started, and when the measured value of the drinking water level sensor falls within the preset maximum water level range, the excellent water level is The device can be deactivated.

In the present invention, the dry season mode starts when the measured value of the storm water level sensor is less than the preset low water level range, and the dry season mode may be terminated when the measured value of the storm water level sensor falls within the preset low water level range.

In the present invention, in the dry season mode, when the measured value of the drinking water level sensor is less than the preset low water level range, the seawater desalination device is started, and when the measured value of the drinking water level sensor falls within the preset medium water level range, the seawater desalination device Can be deactivated.

In the present invention, a solar power unit having a solar panel is further provided, and it is possible to supply driving power for the control unit, the seawater desalination apparatus, and the excellent water purification apparatus.

In the present invention, a rainwater collecting part is provided below the solar panel, so that rainwater flowing down along the solar panel can be transferred to the rainwater storage part.

In the present invention, the seawater desalination apparatus may be filtered by a seawater filter, and supplied to the seawater desalination unit by a seawater pump.

In the present invention, a first three-way branch is provided on one side of the concentrated seawater discharge pipe for discharging the concentrated seawater from the seawater desalination unit to the concentrated seawater storage unit, and a second branch is provided on one side after passing the seawater filter from the seawater inlet pipe. A three-way branch is provided, and the control unit may control the first three-way branch and the second three-way branch so that the discharged concentrated seawater is re-introduced into the seawater desalination unit.

In the present invention, a seawater concentration sensor is provided on one side of the concentrated seawater discharge pipe or on one side of the concentrated seawater storage unit, and when the measured value of the seawater concentration sensor does not reach a preset concentration value, the first 3-way branch is It is possible to block discharge to the concentrated seawater storage unit, the second 3-way branch unit to block the inflow of seawater that has passed through the seawater filter, and allow the discharged concentrated seawater to be re-introduced to the seawater desalination unit.

In the present invention, the rainwater water purification device may be filtered by a rainwater filter, the rainwater introduced through the rainwater inlet pipe communicated with the rainwater storage unit, and supplied to the rainwater purification unit by the rainwater pump.

The combined control mode system of the seawater desalination apparatus and the storm water purification apparatus according to the present invention has the following effects.

First, there is an effect of saving energy and increasing the efficiency of drinking water production by maximizing the use of rainwater resources (excellent water) with low power consumption costs.

Second, there is an effect of desalination of seawater for the shortage of drinking water that may occur during the dry season.

Third, there is an effect of self-supplying an energy source by providing independent supply using photovoltaic power generation.

Fourth, there is an effect of securing a high concentration of concentrated seawater by using a seawater concentration sensor and a 3-way branch.

The effects of the present invention are not limited to those mentioned above, and other effects not mentioned will be clearly understood by those skilled in the art from the following description.

1 is a schematic diagram of an installation of a complex control mode system of a seawater desalination apparatus and an excellent water purification apparatus according to the present invention.
Figure 2 is an operation configuration diagram of the complex control mode system of the seawater desalination device and the storm water purification device according to the present invention.
3 is an embodiment of a time chart of a change in a control mode according to a change in a water level in a rainwater storage unit.
4 is an embodiment of an operation control time chart according to a water level of a drinking water storage unit in a normal season mode.
5 is an embodiment of an operation control time chart according to a water level of a drinking water storage unit in a rainy season mode.
6 is an embodiment of an operation control time chart according to a water level of a drinking water storage unit in a dry season mode.
7 and 8 are embodiments of a control circuit diagram of a complex control mode system of a seawater desalination apparatus and a storm water purification apparatus according to the present invention.

Hereinafter, embodiments of the present invention will be described with reference to the accompanying drawings so that those of ordinary skill in the art can easily implement the present invention. As those of ordinary skill in the art to which the present invention pertains can be easily understood, the following embodiments may be modified in various forms without departing from the concept and scope of the present invention. As far as possible, the same or similar parts are indicated using the same reference numerals in the drawings.

The terminology used in this specification is for referring only to specific embodiments and is not intended to limit the present invention. Singular forms as used herein also include plural forms unless the phrases clearly indicate the opposite.

As used herein, the meaning of "comprising" specifies a particular characteristic, region, integer, step, action, element and/or component, and other specific characteristic, region, integer, step, action, element, component and/or It does not exclude the presence or addition of the military.

All terms including technical and scientific terms used in the present specification have the same meaning as commonly understood by one of ordinary skill in the art to which the present invention belongs. The terms defined in the dictionary are further interpreted as having a meaning consistent with the related technical literature and the presently disclosed content, and are not interpreted in an ideal or very formal meaning unless defined.

The present invention relates to a rainwater purifying apparatus for supplying drinking water to coastal areas and islands where drinking water is very scarce. In case of shortage of rainwater during the dry season, it is related to a technology that desalizes seawater to solve the problem, independently produces the power required for the device, and increases potable water productivity and reduces the production cost of drinking water by effectively using the concomitantly produced seawater concentrated water.

Hereinafter, the present invention will be described with reference to the drawings. For reference, the drawings may be partially exaggerated to describe the features of the present invention. In this case, it is preferable to be interpreted in light of the entire purpose of this specification.

1 is a schematic diagram of an installation of a complex control mode system of a seawater desalination apparatus and an excellent water purification apparatus according to the present invention. Figure 2 is an operation configuration diagram of the complex control mode system of the seawater desalination device and the storm water purification device according to the present invention.

As shown in FIG. 1, a solar power supply unit 700 including a solar panel 710 is provided on a roof of a building, and an accessory device (such as an inverter) is provided inside the building to generate electric power.

In addition, rainwater falling on the solar panel 710 in rainy weather may be collected in the large-scale rainwater storage unit 300 below through the rainwater collecting unit 210. Furthermore, it will be possible to add rainwater falling on the surrounding floor and near valley water.

The present invention relates to a complex control mode system controlled by a controller 600 having a computing means, and to a complex control mode system of a seawater desalination apparatus and a storm water purification apparatus.

The complex control mode system of the seawater desalination apparatus and the stormwater purification apparatus according to the present invention comprises: a seawater desalination apparatus 100 in which seawater is introduced and desalized; Rainwater purification device 200 for purifying stored rainwater; A rainwater storage unit 300 provided with a rainwater level sensor 310 on one side of supplying the stored rainwater to the rainwater purification device 200; A drinking water storage unit 400 that stores drinking water desalted by the seawater desalination apparatus 100 and drinking water purified by the excellent water purification apparatus 200, and having a drinking water level sensor 410 on one side thereof; And a concentrated seawater storage unit 500 for storing concentrated seawater discharged from the seawater desalination apparatus 100.

3 is an embodiment of a time chart of a change in a control mode according to a change in a water level in a rainwater storage unit. The low water level range (L-RW), the medium water level range (M-RW), and the highest water level range (HH-RW) of the rain water (RW) stored in the rainwater storage are presented.

The rainy season mode (R-Mode), the normal season mode (N-Mode), and the dry season mode (D-Mode) according to the present invention are the divisions of the present invention according to the measured value of the water level sensor, and the rainy season in the actual climate , May not coincide with the normal season and the dry season.

In the present invention, the control unit 600 receiving the measured values of the storm water level sensor 310 and the drinking water level sensor 410 may be configured to set the seawater desalination device and the storm water purification device in any one of a normal season mode, a rainy season mode, or a dry season mode. Can be controlled by mode.

First, we will explain the normal season mode.

4 is an embodiment of an operation control time chart according to a water level of a drinking water storage unit in a normal season mode. The low level range (L-RW), the medium level range (M-RW), the high level range (H-RW), and the highest level range (HH-RW) of drinking water stored in the drinking water storage unit are presented. have.

In the present invention, the normal season mode starts when the measured value of the storm water level sensor 310 falls within the preset low water level range, and the measured value of the storm water level sensor 310 falls within the preset maximum water level range. When the normal season mode can be ended.

In the normal season mode, when the measured value of the drinking water level sensor 410 is less than the preset low water level range, the excellent water purification device 200 starts to be driven, and when the measured value of the drinking water level sensor 410 falls within the preset high water level range. The storm water purification device can be deactivated.

The storm water level sensor is involved in the start and end of the smooth season mode according to the present invention, and even if the smooth season mode is started, the storm water purification device does not necessarily operate. The drinking water level sensor is involved in driving and releasing the storm water purification system. This principle can be applied equally to the rainy season and the dry season.

The normal season mode will be described in more detail as follows.

A state in which low water levels (L, RW) are not detected in the rainy season (R mode) and the rainy water level sensor 310 is not detected (eg, 20% or more) is the normal season mode (N mode).

In the normal season mode, when a low water level (L, FW) is detected by the drinking water level sensor 410 according to the setting of the control unit 600 (for example, 20% or less), the high water level (H, FW) of the drinking water storage unit 410 is The excellent water purification device 200 may be operated until it is detected (eg, 80% or more). In this case, the rainwater is purified through the rainwater inlet pipe 220, the rainwater filter 230, the rainwater pump 240, and the rainwater purification unit 250. Thereafter, the purified drinking water is collected into the drinking water storage unit 400 through the drinking water discharge pipe 260 of the storm water purification unit.

Next, the rainy season mode will be described.

5 is an embodiment of an operation control time chart according to a water level of a drinking water storage unit in a rainy season mode. The low level range (L-RW), the medium level range (M-RW), the high level range (H-RW), and the highest level range (HH-RW) of drinking water stored in the drinking water storage unit are presented. have.

In the present invention, the rainy season mode starts when the measured value of the storm water level sensor 310 falls within the preset maximum water level range, and the rainy season starts when the measured value of the storm water level sensor 310 is less than the preset medium water level range. The mode can be ended.

In the rainy season mode, when the measured value of the drinking water level sensor 410 is less than the preset medium water level range, the excellent water purification device starts to operate, and when the measured value of the drinking water level sensor 410 falls within the preset maximum water level range The device can be deactivated.

While performing the rainy season mode, if it is determined that the measured value of the storm water level sensor 310 belongs to the preset medium water level, the controller 600 may cancel the rainy season mode and switch to the normal season mode.

The rainy season mode will be described in more detail as follows.

When rain falls for a long period of time, the amount of rainwater inflow is greater than that of drinking water production, so that the water level of the rainwater storage unit 300 rises. When the storm water level sensor 310 is detected up to the highest water level (HH, RW) (for example, 90%), it becomes the rainy season (R mode).

When the rainfall is reduced and the water level of the rainwater storage unit 300 is lowered and the rainwater level sensor 310 detects the medium water level (M, RW) (e.g., 50%), the rainy season (R mode) is canceled and the normal season (N mode) Return to ).

Depending on the setting of the control unit 600 (eg, 90 to 50%), the rainy season (R mode) operation may be prioritized.

In the rainy season (R mode), when the drinking water level sensor 410 releases the detection of the medium water level (L, FW) according to the setting of the control unit 600 (e.g., 50% or less), the drinking water level sensor 410 is the highest level (HH, FW). The excellent pump 240 may be operated until FW) is detected (eg, 90% or more).

In this mode, the drinking water purified by passing through the storm water inlet pipe 220, the storm filter 230, the storm pump 240, and the storm water purification part 250, the drinking water storage part 400 through the drinking water discharge pipe 260 of the storm water purification part. As it is collected, the amount of rainwater and drinking water storage is maximized.

Next, the dry season mode will be described.

6 is an embodiment of an operation control time chart according to a water level of a drinking water storage unit in a dry season mode. The low level range (L-RW), the medium level range (M-RW), the high level range (H-RW), and the highest level range (HH-RW) of drinking water stored in the drinking water storage unit are presented. have.

In the present invention, the dry season mode starts when the measured value of the storm water level sensor 310 is less than the preset low water level range, and the dry season mode starts when the measured value of the storm water level sensor 310 again falls within the preset low water level range. May be terminated.

In the dry season mode, when the measured value of the drinking water level sensor 410 is less than the preset low water level range, the seawater desalination device starts to drive, and when the measured value of the drinking water level sensor 410 falls within the preset medium water level range, the seawater desalination device Can be deactivated.

The dry season mode will be described in more detail as follows.

The low water level (L, RW) is detected (20% or less) by the storm water level sensor 310 because it does not rain for a long period of time in the dry season mode (D mode).

When a low water level (L, FW) is detected by the drinking water level sensor 410 according to the setting of the control unit 600 (eg, 20% or less), when a medium water level (M, FW) is detected by the drinking water storage unit 400 (For example, the seawater pump 130 can be operated up to 50%).

In this mode, the drinking water that has completed desalination passing through the seawater inlet pipe 110, the seawater filter 120, the seawater pump 130, and the seawater desalination unit 140 is a drinking water storage unit through the drinking water discharge pipe 150 of the seawater desalination unit. It is collected at (400) to minimize the amount of drinking water storage.

For reference, the drinking water discharge pipe 150 of the seawater desalination unit and the drinking water discharge pipe 260 of the storm water purification unit may be provided separately or may be integrated.

Table 1 below shows an example of the capacity of the rainwater storage unit and the drinking water tank facility according to the drinking water production capacity. Here, 10% of the water level in the drinking water storage unit corresponds to the weekly drinking water production for one day.

Table 2 below shows the mode change according to the setting of the control unit and an embodiment of the main operation unit. Here, the control unit is connected to the storm water level sensor and the drinking water level sensor.

The setting of each water level range can be changed according to the situation.

For example, the low water level range can be set as (20% or more to 50% or less), (20% to more than 50%), (20% to less than 50%), (18% or more to 24% or less) ), etc. can be set in various ways. Even in the case of other water level ranges such as the medium water level range, the high water level range, and the highest water level range, it will be possible to appropriately set and change the range while not overlapping with each other.

In the present invention, a preset range to which the measured value of the water level sensor belongs is derived, and a preset operation may be performed in the derived range.

In the present invention, a solar power supply unit 700 having a solar panel 710 is further provided, and it is possible to supply driving power for the control unit, the seawater desalination apparatus, and the excellent water purification apparatus.

A rainwater collecting part 210 is provided below the solar panel 710 according to the present invention, and rainwater flowing down along the solar panel can be transferred to the rainwater storage unit 300.

The seawater desalination apparatus 100 according to the present invention may be filtered by the seawater filter 120, which is introduced through the seawater inlet pipe 110, and supplied to the seawater desalination unit 140 by the seawater pump 130. .

In the present invention, a first three-way branch 170 is provided on one side of the concentrated seawater discharge pipe 160 for discharging the concentrated seawater from the seawater desalination unit 140 to the concentrated seawater storage unit 500, and the seawater inflow After passing through the seawater filter 120 in the pipe 110, a second 3-way branch 180 is provided, and the control unit 600 re-inflows the discharged concentrated seawater back to the seawater desalination unit 140 It is possible to control the first three-way branch unit 170 and the second three-way branch unit 180 as possible.

In the present invention, a seawater concentration sensor 510 is provided on one side of the concentrated seawater discharge pipe 160 or on one side of the concentrated seawater storage unit 500, and the measured value of the seawater concentration sensor 510 corresponds to a preset concentration value. If not reached, the first three-way branch unit 170 blocks the discharge of concentrated seawater to the concentrated seawater storage unit 500, and the second three-way branch unit 180 is the seawater passing through the seawater filter 120. Blocking the inflow of, the discharged concentrated seawater can be re-inflowed into the seawater desalination unit 140.

Through this configuration of re-inflow of concentrated seawater, it is possible to increase the desalination rate of seawater, and by increasing the concentration of the discharged concentrated seawater, the concentrated seawater can be used for processing agricultural and marine products.

The concentrated seawater discharged at the same time as drinking water may be used in the concentrated seawater storage unit 500 through the concentrated seawater discharge pipe 160 for use in low audio, a separate agricultural and marine product processing facility.

When high-salt condensed seawater is required according to agricultural and marine products processing use, if the control unit 600 sets the condensed seawater discharge salinity, the first three-way branch 170 until the salinity of the condensed seawater discharge pipe 160 reaches the set value. And by controlling the opening and closing of the secondary 3-way branch unit 180, the discharged concentrated seawater is re-inflowed. At this time, the bypass pump 190 may be operated.

If a specific agricultural and marine product processed product requires excessive concentration of seawater, there may be a situation in which a load is placed on the seawater desalination unit. In this case, the seawater desalination unit 140 may be operated below the protection limit, and by adding a sea salt or the like to the concentrated seawater storage unit 500, it will be possible to manufacture and use the required salinity.

In addition, when new seawater is introduced, it must pass through the seawater filter 120, but when the discharged concentrated seawater is re-introduced, the seawater filter 120 is not passed through. For this reason, it can also have an effect of saving a seawater filter and required energy.

In the excellent water purification device 200 according to the present invention, the rainwater introduced through the rainwater inlet pipe 220 communicated with the rainwater storage unit 300 is filtered by the rainwater filter 230, and the rainwater purification unit 200 is performed by the rainwater pump 240. It can be supplied as 250.

7 and 8 are embodiments of a control circuit diagram of a complex control mode system of a seawater desalination apparatus and a storm water purification apparatus according to the present invention.

In the case of independent solar power generation, a seawater desalination system that consumes a lot of electricity (about 7 times that of an excellent water purification system) operates only during the daylight hours (solar power generation time) to secure drinking water and stops after sunset, which is an expensive power storage device. Can be minimized.

The electronic 24-hour timer (seasonal sunset, sunrise time correction) is desalination of seawater by serializing the timer and UVR (shortage voltage relay) installed on the power supply side when there is no sunlight for a long time due to cloudy weather even during daylight hours. The device can be controlled (see Figs. 7 and 8).

The embodiments described in the present specification and the accompanying drawings are merely illustrative of some of the technical ideas included in the present invention. Accordingly, it is obvious that the embodiments disclosed in the present specification are not intended to limit the technical idea of the present disclosure, but to explain the technical idea, and thus the scope of the technical idea of the present disclosure is not limited by these embodiments. Modification examples and specific embodiments that can be easily inferred by those skilled in the art within the scope of the technical idea included in the specification and drawings of the present invention should be interpreted as being included in the scope of the present invention.

100: seawater desalination device 110: seawater inlet pipe
120: sea water filter 130: sea water pump
140: seawater desalination unit 150: drinking water discharge pipe of seawater desalination unit
160: concentrated seawater discharge pipe 170: 1st 3-way branch
180: 2nd 3-way branch 190: bypass pump
200: rainwater purification device 210: rainwater collection unit
220: storm inlet pipe 230: storm filter
240: excellent pump 250: excellent water purification unit
260: drinking water discharge pipe of the rainwater purification department
300: rainwater storage unit 310: rainwater level sensor
400: drinking water storage unit 410: drinking water level sensor
500: concentrated seawater storage unit 510: seawater concentration sensor
600: control unit
700: solar power unit 710: solar panel

Claims (13)

delete As a complex control mode system controlled by a control unit having a computing means,
A seawater desalination device for desalination by introducing seawater; A rainwater purification device that purifies the stored rainwater; A rainwater storage unit supplying the stored rainwater to the rainwater purification device, and having a rainwater level sensor on one side thereof; A drinking water storage unit storing drinking water desalted by the seawater desalination device and drinking water purified by the excellent water purification device, and having a drinking water level sensor on one side thereof; And a concentrated seawater storage unit for storing concentrated seawater discharged from the seawater desalination device,
The control unit receiving the measured values of the storm water level sensor and the drinking water level sensor controls the seawater desalination device and the storm water purification device in any one of a normal season mode, a rainy season mode, or a dry season mode,
The normal season mode is characterized in that the normal season mode starts when the measured value of the storm water level sensor falls within the preset low water level range, and the normal season mode ends when the measured value of the storm water level sensor falls within the preset maximum water level range. Combined control mode system of seawater desalination system and storm water purification system. The method according to claim 2,
In normal season mode,
When the measured value of the drinking water level sensor is less than the preset low water level range, the excellent water purification device starts to operate.
A combined control mode system of a seawater desalination device and a stormwater purification device, characterized in that the excellent water purification device is deactivated when the measured value of the drinking water level sensor falls within the preset high water level range. As a complex control mode system controlled by a control unit having a computing means,
A seawater desalination device for desalination by introducing seawater; A rainwater purification device that purifies the stored rainwater; A rainwater storage unit supplying the stored rainwater to the rainwater purification device, and having a rainwater level sensor on one side thereof; A drinking water storage unit storing drinking water desalted by the seawater desalination device and drinking water purified by the excellent water purification device, and having a drinking water level sensor on one side thereof; And a concentrated seawater storage unit for storing concentrated seawater discharged from the seawater desalination device,
The control unit receiving the measured values of the storm water level sensor and the drinking water level sensor controls the seawater desalination device and the storm water purification device in any one of a normal season mode, a rainy season mode, or a dry season mode,
In the rainy season mode, the rainy season mode starts when the measured value of the storm water level sensor falls within the preset maximum water level range, and the rainy season mode ends when the measured value of the storm water level sensor falls within the preset medium water level range. Complex control mode system of equipment and storm water purification equipment. The method of claim 4,
In the above rainy season mode,
When the measured value of the drinking water level sensor is less than the pre-set medium water level, the excellent water purification device starts to operate.
A combined control mode system of a seawater desalination device and a stormwater purification device, characterized in that when the measured value of the drinking water level sensor falls within the preset maximum water level range, the storm water purification device is deactivated. As a complex control mode system controlled by a control unit having a computing means,
A seawater desalination device for desalination by introducing seawater; A rainwater purification device that purifies the stored rainwater; A rainwater storage unit supplying the stored rainwater to the rainwater purification device, and having a rainwater level sensor on one side thereof; A drinking water storage unit storing drinking water desalted by the seawater desalination device and drinking water purified by the excellent water purification device, and having a drinking water level sensor on one side thereof; And a concentrated seawater storage unit for storing concentrated seawater discharged from the seawater desalination device,
The control unit receiving the measured values of the storm water level sensor and the drinking water level sensor controls the seawater desalination device and the storm water purification device in any one of a normal season mode, a rainy season mode, or a dry season mode,
In the dry season mode, the dry season mode starts when the measured value of the storm water level sensor is less than the preset low water level range, and the dry season mode ends when the measured value of the storm water level sensor falls within the preset low water level range. Combined control mode system of storm water purification system. The method of claim 6,
In the dry season mode state,
When the measured value of the drinking water level sensor is less than the preset low water level range, the seawater desalination system starts to operate.
A combined control mode system of a seawater desalination device and a storm water purification device, characterized in that the seawater desalination device is deactivated when the measured value of the drinking water level sensor falls within a preset medium water level range. The method according to any one of claims 2, 4 or 6,
A combined control mode system of a seawater desalination device and a stormwater water purification device, characterized in that it is further provided with a photovoltaic power unit having a photovoltaic panel to supply driving power for a control unit, a seawater desalination device, and an excellent water purification device. The method of claim 8,
A combined control mode system of a seawater desalination device and a stormwater purification device, characterized in that a rainwater collecting unit is provided below the solar panel to transfer rainwater flowing along the solar panel to the rainwater storage unit. The method according to any one of claims 2, 4 or 6,
The seawater desalination device
A combined control mode system of a seawater desalination device and an excellent water purification device, characterized in that the seawater introduced through the seawater inlet pipe is filtered by a seawater filter and supplied to the seawater desalination unit by a seawater pump. The method of claim 10,
A first three-way branch is provided on one side of the concentrated seawater discharge pipe for discharging the concentrated seawater from the seawater desalination unit to the concentrated seawater storage unit,
A second three-way branch is provided on one side after passing through the seawater filter in the seawater inlet pipe,
The control unit controls the first 3-way branch and the second 3-way branch so that the discharged concentrated seawater is re-introduced into the seawater desalination unit. The method of claim 11,
A seawater concentration sensor is provided on one side of the concentrated seawater discharge pipe or on one side of the concentrated seawater storage unit,
If the measured value of the seawater concentration sensor does not reach a preset concentration value,
The first 3-way branch blocks the discharge of concentrated seawater to the concentrated seawater storage unit,
The 2nd 3-way branch blocks the inflow of seawater that has passed through the seawater filter,
A combined control mode system of a seawater desalination device and an excellent water purification device, characterized in that the discharged concentrated seawater is re-introduced into the seawater desalination unit. The method according to any one of claims 2, 4 or 6,
The excellent water purification device
A combined control mode system of a seawater desalination device and a stormwater purification device, characterized in that the rainwater introduced through the rainwater inlet pipe communicated with the rainwater storage section is filtered by the rainwater filter and supplied to the rainwater purification section by the rainwater pump.

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