KR20230075134A - Mixed liquid separator - Google Patents

Abstract

The disclosed invention relates to a mixed liquid separation device which comprises: a separation tank into which a mixed liquid of a first liquid of high specific gravity and a second liquid of low specific gravity is introduced to one side; a first discharge port disposed on the other side of the separation tank and disposed downward along a vertical direction and a second discharge port disposed upward; a water level measuring unit disposed in an area in which the mixed liquid is separated into a first liquid and a second liquid by the difference in specific gravity to form an interface and measuring at least two water levels of a first water level between the bottom and the interface, a second water level between an liquid surface and the interface, and a total water level between the liquid surface and the bottom; a first valve operating the opening and closing of the first discharge port and a second valve operating the opening and closing of the second discharge port; and a controlling unit controlling the first valve and the second valve based on a signal received from the water level measuring unit, wherein the controlling unit performs control to open the first discharge port only when the first water level is in a preset first range and also performs control to open the second discharge port only when the second water level is in a preset second range. If the mixed liquid separation device of the present invention is expanded to a ship structure or equipped on a ship, the mixed liquid separation device can be used as a skimmer recovering oil such as crude oil spilled in freshwater or seawater, so the effectiveness of the mixed liquid separation device is very high.

Description

Mixed liquid separator {MIXED LIQUID SEPARATOR}

The present invention relates to an apparatus for separating a mixture of liquids having different specific gravity by specific gravity through a physical method.

Wastewater, which is a mixture of several liquids with different specific gravity, for example, oil and water, is discharged in large quantities not only from industrial sites such as factories, construction sites, and ships, but also from real life such as restaurants and homes.

If the mixed solution is discharged as it is without separate treatment, it often causes great damage to the natural ecosystem, so a pre-treatment process is required before discharging various mixed solutions into nature.

Examples of methods for separating liquids before mixing in mixed liquids having different specific gravity include specific gravity treatment, hydraulic separation, filter separation, and the like.

As a specific gravity separation method, for example, a method using a specific gravity difference, such as suspending oil on water for a mixture of water and oil and then removing it by skimming with an oil skimmer. However, the specific gravity separation method can be applied only to large-scale facilities such as sewage treatment plants that can create stagnation or slow flow in the mixed pressure core flow as installation space and power are required to float liquids with low specific gravity and operate the skimmer. The downside is that it is somewhat inconvenient.

The hydraulic separation method is a method of separating by centrifugal force and gravity by forming a specific flow pattern such as a vortex in a limited space. However, the hydraulic separation method has a fundamental limitation that complete separation is difficult because it is a method of sucking and removing the low specific gravity liquid suspended at the top.

The filter separation method is a method of filtering one kind of liquid using a filter cloth such as non-woven fabric and passing the remaining liquid. However, the filter separation method has a problem in that, when the amount of liquid to be filtered is large, it may leak out without being filtered out, and since filter replacement or cleaning is required regularly, maintenance costs are high and continuous separation treatment is difficult.

Korean Registered Patent No. 10-1726402 (registered on 2017.04.06)

An object of the present invention is to provide a liquid mixture separator capable of separating liquid mixtures of different specific gravities by specific gravity, having a simple structure, simple maintenance, and continuously processing a large amount of liquid mixture.

The present invention relates to a mixed liquid separation device, comprising: a separation tank into which a mixture of a high specific gravity first liquid and a low specific gravity second liquid is input to one side; A first discharge port disposed on and a second discharge port disposed above; and, the mixed liquid is separated into the first liquid and the second liquid by the difference in specific gravity to form an interface, and the first liquid between the bottom and the interface is disposed. A water level measuring unit for measuring at least two of the water level, the second water level between the liquid surface and the interface, and the total water level between the liquid surface and the bottom; and a first valve for manipulating opening and closing of the first outlet and a second outlet A second valve for opening and closing; and a controller configured to control the first valve and the second valve based on a signal received from the water level measurement unit, wherein the controller may control the first water level only when the first water level is within a preset first range. 1 control to open the outlet, and also perform control to open the second outlet only when the second water level is within a preset second range.

Here, the first range may be set to a range in which the first water level is greater than or equal to a first boundary water level set between the first outlet and the second outlet.

Accordingly, the control unit may perform control to switch the closed state of the first valve into an open state when the first water level reaches a position obtained by adding a first clearance height above the first boundary water level.

The second range may be set to a range in which the first water level is less than or equal to a second boundary water level set between the second outlet and the first boundary water level.

Accordingly, the control unit may perform control to switch the closed state of the second valve to an open state when the first water level reaches a position obtained by subtracting the second clearance height above the second boundary water level.

Alternatively, the second range may include a range in which the first water level is less than or equal to the second boundary water level set between the second outlet and the first boundary water level, and at the same time, the total water level is greater than or equal to the third boundary water level set above the second outlet. may be set to

Accordingly, the control unit, when the first water level reaches a position obtained by subtracting the second marginal height above the second boundary water level, and at the same time, the entire water level reaches a position obtained by adding the third marginal height to the third boundary water level It is possible to perform control to convert the closed state of the second valve into an open state.

On the other hand, in one embodiment of the present invention, the level measuring unit is an interface located on the interface between the first liquid and the second liquid by being made of an intermediate specific gravity between the specific gravity of the first liquid and the specific gravity of the second liquid A floating body is provided, and the interface floating body provides a reference for a first water level between the bottom and the interface or a second water level between the liquid surface and the interface.

In addition, the water level measurement unit includes a liquid surface floating body having a specific gravity lighter than that of the second liquid, and the first water level between the bottom and the interface and between the liquid surface and the interface using the liquid surface floating body and the interface floating body as standards. At least two or more of the second water level and the total water level between the liquid level and the bottom may be measured.

And, according to an embodiment of the present invention, the second outlet may be a fixed second outlet having a fixed distance from the first outlet, or a movable second outlet having a variable distance from the first outlet. can

In the movable second outlet, an inlet into which the second liquid flows is located on the surface of the second liquid, and an outlet through which the inflowed second liquid flows out is connected to the inlet through a pipe member and extends outside the separation tank. can

Here, the movable second outlet may be a floating type having a specific gravity lighter than that of the second liquid, or a power driving type that moves under the control of the control unit based on the total water level measured by the water level measuring unit. can

Also, the height of the outlet of the movable second outlet may be less than the first water level.

The liquid mixture separator of the present invention having the configuration as described above can rapidly and continuously separate liquid mixtures in which liquids having different specific gravity are mixed by specific gravity. In particular, since liquids having different specific gravities are simultaneously separated and discharged, the separation throughput per hour is very high.

In addition, since the mixed liquid separator of the present invention has a simple structure and almost no consumables, maintenance costs are greatly reduced. Therefore, since the investment cost is not an obstacle even when configuring large facilities, it is possible to promote the expansion of facilities for treating various wastewater.

In addition, if the mixed liquid separation device of the present invention is expanded to a ship structure or provided in a ship, it can be used as a skimming boat for recovering oil such as crude oil leaked into fresh water or seawater, and its effectiveness is very high.

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

1 is a view showing the overall configuration of a mixed liquid separator according to the present invention.
Fig. 2 shows an embodiment for a first range set for a first outlet;
Fig. 3 shows an embodiment of a second range set for a second outlet;
Fig. 4 shows another embodiment for a second range set for a second outlet;
5 is a view showing a water level measuring unit according to an embodiment of the present invention.
Fig. 6 shows an example of a movable second outlet with a variable distance to the first outlet;

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. Advantages and features of the present invention, and methods for achieving them, will become clear with reference to the embodiments described below in detail in conjunction with the accompanying drawings. However, the present invention is not limited to the embodiments disclosed below, but may be implemented in various different forms, and only the present embodiments make the disclosure of the present invention complete, and common knowledge in the art to which the present invention belongs. It is provided to fully inform the holder of the scope of the invention, and the present invention is only defined by the scope of the claims. Like reference numbers designate like elements throughout the specification.

Unless otherwise defined, all terms (including technical and scientific terms) used in this specification may be used in a meaning commonly understood by those of ordinary skill in the art to which the present invention belongs. In addition, terms defined in commonly used dictionaries are not interpreted ideally or excessively unless explicitly specifically defined. Terms used in this specification are for describing embodiments and are not intended to limit the present invention. In this specification, singular forms also include plural forms unless specifically stated otherwise in a phrase.

As used herein, "comprises" and/or "comprising" means that a stated component, step, operation, and/or element is one or more other components, steps, operations, and/or elements. Existence or additions are not excluded.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings. 1 shows the overall configuration of a mixed liquid separator 10 according to the present invention.

Referring to FIG. 1, the mixed liquid separator 10 of the present invention includes a separation water tank 100, a first outlet 200 and a second outlet 300, a water level measurement unit 400, and a control unit 500. do.

The separation tank 100 is a container into which the mixed liquid ML is injected, and the mixed liquid ML injected into one side of the separation water tank 100 includes a first liquid L1 of high specific gravity and a second liquid L2 of low specific gravity. is a liquid mixed with The size of the separation water tank 100 is made to a suitable size according to the purpose of the mixed liquid separation device 10, and may have a lid if necessary. can be determined

For reference, the present invention is for separating a mixed liquid (ML) in which a first liquid (L1) of high specific gravity and a second liquid (L2) of low specific gravity are mixed into a first liquid (L1) and a second liquid (L2). , In order to facilitate the understanding of the invention, each component to be described below is referred to as “first to” that is mainly related to the first liquid (L1) and to “second to” that is mainly related to the second liquid (L2). will refer

The first outlet 200 and the second outlet 300 are disposed on the other side of the separating water tank 100 . The first outlet 200 forms a passage through which the first liquid L1 is discharged, and since the first liquid L1 having a relatively high specific gravity gathers at the bottom of the separation water tank 100, the first outlet 200 has placed underneath In addition, the second outlet 300 forming a discharge passage for the second liquid L2 of low specific gravity is disposed above the first outlet 200 along the vertical direction.

However, the fact that the second outlet 300 is disposed above the first outlet 200 in the vertical direction only specifies a vertical positional relationship, and the first outlet 200 and the second outlet 300 are arranged in a straight line in the vertical direction. That doesn't mean it's on top.

Here, the fact that the first outlet 200 and the second outlet 300 are disposed on the other side of the separation tank 100 means that they are spaced apart by an appropriate distance from the input of the mixed liquid ML to one side of the separation tank 100. meaning is implied. That is, in the first outlet 200 and the second outlet 300, the mixed liquid ML injected into one side of the separation water tank 100 has a clear difference between the first liquid L1 and the second liquid L2 due to the difference in specific gravity. They need to be separated by a sufficient distance to form the interface FC.

In addition, shock generated when the mixed liquid ML is introduced into the separation tank 100 is prevented from causing disturbance around the first outlet 200 and the second outlet 300, and the first liquid L1 and the second outlet 300 are prevented. In order to control the flow rate of the two liquids (L2) and induce rapid separation of the first liquid (L1) and the second liquid (L2) up and down, it is also preferable that the flow control plate 110 is provided at an appropriate location and depth. can do.

The water level measurement unit 400 is a component corresponding to a water level sensor that measures the water level of each of the first liquid L1 and the second liquid L2 separated up and down. In particular, the water level measuring unit 400 provided in the present invention can measure the water level or height of the interface FC formed between the first liquid L1 and the second liquid L2 separated to form an upper and lower layer. It has a characteristic.

An embodiment of the water level measurement unit 400 will be described in detail in a corresponding section, and if its basic function or role is summarized, the water level measurement unit 400 measures the first water level LV1 between the floor and the interface FC, At least two of the second water level LV2 between the liquid surface and the interface FC and the total water level TL between the liquid surface and the bottom may be measured.

Since the sum of the first water level LV1 and the second water level LV2 is the total water level TL, even if only two of these three water levels are measured, both water levels can be known through calculation. Here, the water level measurement unit 400 should be disposed in a region where the liquid mixture ML is separated into the first liquid L1 and the second liquid L2 by the difference in specific gravity to form an interface FC stably. am.

The first outlet 200 and the second outlet 300 are provided with a first valve 210 and a second valve 310 responsible for opening and closing, respectively. The opening and closing of the first valve 210 is appropriately controlled to prevent the second liquid L2 other than the first liquid L1 from being discharged through the first outlet 200, and similarly, the second valve 310 The first liquid L1 is prevented from being discharged through the second outlet 300 . The operation of the first valve 210 and the second valve 310 is performed by the control unit 500 .

The control unit 500 controls the operation of the first valve 210 and the second valve 310 based on the signal received from the water level measuring unit 400 . Specifically, the control unit 500 performs control to open the first outlet 200 only when the first water level LV1 is within a preset first range 510, and also controls that the second water level LV2 is in the preset range 510. Control to open the second outlet 300 is performed only when it is within the second range 520 set in . That is, the first range 510 refers to a range in which the first liquid L1 can be specified as existing around the first outlet 200, and when viewed from the perspective of the first outlet 200, the first The first valve 210 is operated to close immediately before the outlet 200 moves out of the first range 510 and is adjacent to or at least enters the second liquid L2. The second range 520 also has the same meaning for the second outlet 300 .

In addition, since the first pump 220 and the second pump 320 are provided at the first outlet 200 and the second outlet 300, respectively, the first liquid L1 and the second liquid (L1) are provided much more quickly than natural discharge. L2) may be discharged to the outside. The operation of the first pump 220 and the second pump 320 is interlocked with the opening operation of the first valve 210 and the second valve 310 under the control of the control unit 500 .

FIG. 2 shows a specific embodiment of the first range 510 set for the first outlet 200 . Referring to FIG. 2, the first range 510 is the first water level LV1, that is, the level of the first liquid L1 from the bottom to the interface FC is the first outlet 200 and the second outlet 300 ) It may be set to a range equal to or greater than the first boundary water level 512 set between.

In other words, the first range 510 means a range in which the first liquid L1 maintains a certain water level above the first outlet 200, and is equal to or higher than the first boundary water level 512 set as a safety value. When the first water level (LV1) is maintained, the first valve 210 is opened, otherwise, the first valve 210 is closed to prevent the second liquid (L2) from flowing out through the first outlet 200. prevent in advance

Furthermore, when the first water level (LV1) falls below the first boundary water level 512 and then rises again, the control unit 500 is located at a position obtained by adding the first marginal height 514 to the first boundary water level 512. When the first water level (LV1) is reached, the control of switching the closed state of the first valve 210 to the open state may be performed. This is in consideration of the problem that the first valve 210 repeatedly opens and closes when the first water level LV1 goes up and down the first boundary water level 512 .

And, FIG. 3 shows a specific embodiment of the second range 520 set for the second outlet 300 . As shown, the second range 520 may be set to a range in which the first water level LV1 is equal to or less than the second boundary water level 522 set between the second outlet 300 and the first boundary water level 512. . The first water level (LV1) is a water level from the bottom to the interface (FC), the first water level (LV1) means the water level of the first liquid (L1) and the bottom surface height of the second liquid (L2) at the same time.

The second boundary water level 522 shown in FIG. 3 is also a kind of safety value, and is the minimum depth of the second liquid L2 to be secured below the second outlet 300, in other words, from the bottom to the interface FC. This means the allowable maximum height of the first water level (LV1), which is a distance of . That is, the fact that the first liquid L1 approaches the second outlet 300 by exceeding the second boundary water level 522 increases the risk of the first liquid L1 leaking through the second outlet 300. , the second boundary water level 522 is a standard for the opening and closing operation of the second valve 310.

In addition, the controller 500 changes the closed state of the second valve 310 to the open state only when the first water level LV1 reaches the position obtained by subtracting the second clearance height 524 from the second boundary water level 522. Switching control can be performed. This is for the same reason as in the case of the first clearance height 514 described above, and prevents the frequent opening and closing of the second valve 310 when the first water level LV1 goes up and down the second boundary water level 522. is to do

4 shows another embodiment for setting the second boundary water level 522 . The other embodiment of FIG. 4 differs in that a third boundary water level 526 is additionally set while including the configuration of FIG. 3 for the second boundary water level 522 as it is.

As shown in FIG. 4, even if the first water level (LV1) is below the second boundary water level 522, when the amount of the second liquid (L2) is small, the surface of the second liquid (L2) is the second discharge port (300) may be below. In other words, in the case of FIG. 4, even if the second outlet 300 is opened, the second liquid L2 cannot be discharged. In this case, the second outlet 300 is opened and the second pump 320 ) need not be run.

Therefore, in another embodiment of FIG. 4 , the second range 520 is equal to or less than the second boundary water level 522 in which the first water level LV1 is set between the second outlet 300 and the first boundary water level 512, and at the same time The total water level TL is set to a range equal to or higher than the third boundary water level 526 set above the second outlet 300 .

And, as the third boundary water level 526 is additionally set, the control unit 500 reaches the position where the first water level LV1 is obtained by subtracting the second marginal height 524 from the second boundary water level 522, and at the same time Control for switching the closed state of the second valve 310 to the open state is performed when the total water level TL reaches a position obtained by adding the third clearance height 528, which is a safety value, to the third boundary water level 526. can

5 shows a water level measurement unit 400 according to an embodiment of the present invention. The illustrated water level measurement unit 400 includes an interface floating body 410 having an intermediate specific gravity between the specific gravity of the first liquid L1 and the specific gravity of the second liquid L2. Since the interface floating body 410 has an intermediate specific gravity between the first liquid L1 and the second liquid L2, it is located on the interface FC between the first liquid L1 and the second liquid L2. Accordingly, the interface floating body 410 provides a reference for a first water level LV1 between the bottom and the interface FC or a second water level LV2 between the liquid surface and the interface FC.

Since the interface floating body 410 is located on the interface FC between the first liquid L1 and the second liquid L2, the first water level between the floor and the interface FC is obtained by using the interface floating body 410. (LV1), a second water level (LV2) between the liquid surface and the interface (FC), and a total water level (TL) between the liquid surface and the bottom may be measured. The distance from a certain point to the interface floating object 410 can be measured using various known distance sensors.

For example, by projecting an ultrasonic distance sensor disposed on the bottom of the separation tank 100 or above the separation tank 100 (eg, a lid or a ceiling of an indoor room) onto the liquid surface and the floating body 410, the lid All desired distances can be grasped through measurement of the distance from the liquid surface or the distance from the lid to the interface floating body 410. The total water level (TL) can be measured very easily using the prior art for measuring the water level, and the first water level (LV1) and the second water level (LV2) can be obtained by combining the distance measured using the interface floating body 410. , and the total water level (TL).

Alternatively, as shown in FIG. 5, the interface floating body 410 moves freely up and down along the rod 430 or rail fixed to the bottom of the separation tank 100 according to the fluctuation of the interface FC, and the interface rises and falls in this way. The position of the floating body 410 can be easily measured using a proximity sensor using light or ultrasonic waves, a hall sensor that responds to a magnetic field, or the like. For reference, sensors such as a known proximity sensor or a distance sensor are omitted in FIG. 5 in order to avoid limiting interpretation of the technical content of the present invention by the measurement method of the sensor.

In addition, the level measuring unit 400 may include a liquid surface floating body 420 having a specific gravity lighter than that of the second liquid L2. The liquid surface floating body 420 can also move only up and down by a rod 430 or a rail, and the control between the floor and the interface FC is made using the two standards of the liquid surface floating body 420 and the interface floating body 410. At least two or more levels of one level (LV1), a second level (LV2) between the liquid level and the interface (FC), and a total level (TL) between the liquid level and the bottom may be measured. When the water level measuring unit 400 is provided with the liquid surface floating body 420, it is advantageous in that sensors such as a proximity sensor or a distance sensor provided with the interface floating body 410 as an object to be inspected can be shared.

Meanwhile, in the mixed liquid separator 10 of the present invention, the second discharge port 300 may be configured as a fixed type as well as a movable one. 1 to 5 show an example composed of a fixed second outlet 301 whose distance to the first outlet 200 is determined as a constant, and FIG. 6 shows an example in which the distance to the first outlet 200 is An example of a variable, movable second outlet 302 is shown.

Referring to FIG. 6, in the movable second outlet 302, the inlet 303 into which the second liquid L2 is introduced is located on the surface of the second liquid L2, and the introduced second liquid L2 is The outflow outlet 304 is connected to the inlet 303 through a pipe member 305 and extends outside the separation water tank 100. Since the inlet 303 of the movable second outlet 302 is located on the surface of the second liquid L2, the surface of the second liquid L2 is below the second outlet 300 as in the example shown in FIG. there is no case Therefore, the aforementioned second range 520 may be specified as one second boundary water level 522 .

The movable second outlet 302 may be made of a floating type having a specific gravity lighter than that of the second liquid L2, or the control unit 500 based on the total water level TL measured by the water level measurement unit 400. ) can be configured as a power driving type that moves under the control of For stable up and down movement of the movable second outlet 302, a transfer rail 306 can be installed vertically in the separating water tank 100 to induce vertical movement, and an electric mechanism (for example, A chain mechanism) or a hydraulic mechanism may be installed to move the movable second outlet 302. In FIG. 6, the illustration of the electric mechanism or the hydraulic mechanism, which is the main technology, is omitted.

And, according to the embodiment, the height of the outlet 304 of the second movable outlet 302 may be less than the first water level LV1. This is to use the siphon effect, and the second liquid L2 can be continuously discharged through the power of the water head formed by the water level (second water level) of the second liquid L2. .

Using the siphon effect is possible because the movable second outlet 302 is always located on the surface of the second liquid L2, and in this case, the second pump 320 is not necessarily required (however, the second External power may be required for initial discharge of liquid). The embodiment using the siphon effect can be particularly useful when configuring the mixed liquid separation device 10 of the present invention in a compact size.

On the other hand, the above description has been made for a mixture of two liquids with different specific gravity, but it is possible to apply it to a mixture of three or more liquids with different specific gravity by extending the operating principle of the present invention described in detail. It will be obvious to those skilled in the art.

Although the embodiments of the present invention have been described with reference to the accompanying drawings, those skilled in the art to which the present invention pertains can be implemented in other specific forms without changing the technical spirit or essential features of the present invention. you will be able to understand Therefore, the embodiments described above should be understood as illustrative in all respects and not limiting.

10: Mixed liquid separator 100: Separation tank
110: flow control plate 200: first outlet
210: first valve 220: first pump
300: second outlet 301: fixed second outlet
302: movable second outlet 303: inlet
304: exit 305: pipe member
306: transfer rail 310: second valve
320: second pump 400: water level measuring unit
410: interface floating body 420: liquid surface floating body
430: load 500: control unit
510: first range 512: first boundary water level
514: first clearance height 520: second range
522: second boundary water level 524: second clearance height
526: 3rd boundary water level 528: 3rd clearance height
ML: mixed liquid L1: first liquid
L2: second liquid FC: interface
LV1: 1st water level LV2: 2nd water level
TL: full water level

Claims (13)

a separation tank into which a mixture of a first liquid with a high specific gravity and a second liquid with a low specific gravity is injected into one side;
a first discharge port disposed on the other side of the separation tank and disposed downward along a vertical direction and a second discharge port disposed upward;
The liquid mixture is separated into a first liquid and a second liquid by a difference in specific gravity to form an interface, and the first water level between the bottom and the interface, the second water level between the liquid surface and the interface, and the entire surface between the liquid surface and the bottom a water level measuring unit for measuring at least two of the water levels;
a first valve for opening and closing the first outlet and a second valve for opening and closing the second outlet; and
a control unit controlling the first valve and the second valve based on the signal received from the water level measuring unit;
including,
The controller performs control to open the first outlet only when the first water level is within a preset first range, and opens the second outlet only when the second water level is within a preset second range. Mixed liquid separator, characterized in that for performing the control to open. According to claim 1,
The first range is a range in which the first water level is greater than or equal to a first boundary water level set between the first outlet and the second outlet. According to claim 2,
The mixed liquid separation device, characterized in that the controller switches the closed state of the first valve to an open state when the first water level reaches a position obtained by adding a first clearance height to the first boundary water level. According to claim 1,
The second range is a range in which the first water level is less than or equal to a second boundary water level set between the second outlet and the first boundary water level. According to claim 4,
The mixed-liquid separation device according to claim 1 , wherein the control unit switches the closed state of the second valve to an open state when the first water level reaches a position obtained by subtracting the second clearance height above the second boundary water level. According to claim 1,
The second range is characterized in that the first water level is less than or equal to the second boundary water level set between the second outlet and the first boundary water level, and at the same time, the entire water level is greater than or equal to the third boundary water level set above the second outlet. Mixed liquid separator to do. According to claim 6,
The controller controls the second boundary water level when the first water level reaches a position obtained by subtracting the second marginal height above the second boundary water level, and at the same time, the total water level reaches a position obtained by adding the third marginal height to the third boundary water level. Mixed liquid separation device, characterized in that for switching the closed state of the valve to the open state. According to claim 1,
The water level measuring unit,
An interface floating body positioned on the interface between the first liquid and the second liquid by having an intermediate specific gravity between the specific gravity of the first liquid and the specific gravity of the second liquid,
The interface floating body provides a reference for a first water level between the bottom and the interface or a second water level between the liquid surface and the interface. According to claim 8,
The water level measuring unit,
A liquid surface floating body made of a specific gravity lighter than the specific gravity of the second liquid,
Characterized in that measuring at least two or more of the first water level between the floor and the interface, the second water level between the liquid surface and the interface, and the total water level between the liquid surface and the bottom based on the liquid surface floating body and the interface floating body Mixed liquid separator. According to claim 1,
The second outlet,
Mixed liquid separator, characterized in that the fixed second outlet with a fixed distance to the first outlet, or a movable second outlet with a variable distance to the first outlet. According to claim 10,
The movable second outlet,
An inlet into which the second liquid flows is located on a surface of the second liquid, and an outlet through which the inflowed second liquid flows out is connected to the inlet by a pipe member and extends outside the separation tank. . According to claim 11,
The movable second outlet,
It is a floating type consisting of a specific gravity lighter than the specific gravity of the second liquid,
or a mixed liquid separator, characterized in that it is a powered driving type that moves under the control of the controller based on the total water level measured by the water level measurement unit. According to claim 12,
Mixed liquid separator, characterized in that the height of the outlet of the movable second outlet is less than the first water level.

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