KR20210141047A - Oil recovery device - Google Patents

Abstract

Disclosed is an oil recovery device to quickly and effectively separate oil and water. According to one aspect of the present invention, an oil recovery device separates a mixed solution in which water and oil are mixed in an emulsion state into oil and water and discharges the oil and the water separately. The oil recovery device comprises: a tank providing an internal space for accommodating a mixed solution and the oil and water separated from the mixed solution, having a mixed solution inlet formed at the front end part of the inner space to pass the mixed solution therethrough, and having an oil outlet and a water outlet at the rear end part of the inner space to discharge the oil and water separated from the mixed solution therethrough, respectively; a separation plate disposed at the rear side of the mixed solution inlet in the inner space, arranged so that one side faces up and the other side faces down, having a plurality of vertical through-holes, and having a lipophilic surface; and a bubble generation unit disposed under the separation plate to generate bubbles.

Description

Oil recovery device

The present invention relates to an oil recovery device.

With the increase in industrial cargo volume, maritime transportation is gradually increasing, and with the increase in large ships, maritime accidents due to ship collisions or other ship strandings occur frequently. Pollution is a serious situation beyond imagination. In other words, a large amount of oil spillage spreads very quickly, and the pollution caused by it is at a level that threatens the entire marine ecosystem.

Marine pollution by oil may occur not only in marine accidents caused by ships and offshore plants, but also by inflow of oil mixed polluted water discharged from land plants, etc. into the ocean.

Therefore, there is an urgent need to develop a technology for recovering oil from water mixed with oil.

An embodiment of the present invention is to provide an oil recovery device configured to effectively recover oil that causes environmental pollution or water pollution.

According to one aspect of the present invention, there is provided an oil recovery device for separating and discharging a mixed solution in which water and oil are mixed in an emulsion state with oil and water, and an internal space for accommodating the mixed solution and the oil and water separated from the mixed solution and , A tank in which a mixed solution inlet through which the mixed solution is introduced is formed at the front end of the inner space, and an oil outlet and a water outlet through which the oil and water separated from the mixed solution are respectively discharged at the rear end of the inner space; a separation plate positioned at the rear of the mixed solution inlet in the inner space, one side facing up and the other side facing down, a plurality of through holes penetrating vertically and having a lipophilic surface; and a bubble generating unit generating bubbles under the separator plate, an oil recovery device may be provided.

A plurality of separation plates may be provided, and the plurality of separation plates may be vertically spaced apart from each other.

The separation plate may have a corrugated structure oscillating up and down, and the plurality of through-holes may be dispersedly disposed in crests and troughs of the corrugated structure.

The oil recovery device may further include a partition wall disposed between the mixed solution inlet and the separation plate, a lower end in contact with the floor of the inner space and a partition wall at an upper end spaced apart from the ceiling of the inner space.

The oil recovery device is disposed at the rear of the separation plate, the oil separated from the mixed solution flows in, an oil receiving space connected to the oil outlet, and water separated from the mixed solution flows in and water receiving connected to the water outlet It may further include a partition for partitioning the space.

The partition unit may include: a first partition member disposed behind the separation plate, the lower end being spaced apart from the bottom of the inner space, and the upper end being spaced apart from the ceiling of the inner space; and a second partition member extending rearward from the rear surface of the first partition member and partitioning upper and lower portions of the rear space of the first partition member into the oil accommodation space and the water accommodation space, respectively.

The oil recovery device is slidably coupled up and down to the front surface of the first partition member, and floats across the interface between oil and water positioned in front of the first partition member, It may further include a float for closing an oil inlet formed between the upper end of the first partition member and the ceiling of the inner space or a water inlet formed between the lower end of the first partition member and the bottom of the inner space according to the height have.

According to an embodiment of the present invention, by generating bubbles under the separator plate having a lipophilic surface and having a plurality of through-holes formed at the rear of the mixed solution inlet, the mixed solution in which water and oil are mixed in an emulsion state is mixed with oil and oil. can be separated quickly and effectively.

1 is a view showing an oil recovery device according to an embodiment of the present invention.
FIG. 2 is an enlarged perspective view of an adjacent pair of the plurality of separation plates shown in FIG. 1 .
FIG. 3 is an enlarged view of a part of one of the plurality of separators illustrated in FIG. 1 .
4 is a view for explaining an example of the coupling structure of the floating body and the first partition member.
5 is a view for explaining an operation example of the floating body.
6 is a view for explaining another operation example of the floating body.
7 is a view for explaining another operation example of the floating body.

Since the present invention can apply various transformations and can have various embodiments, specific embodiments are illustrated in the drawings and described in detail in the detailed description. However, this is not intended to limit the present invention to specific embodiments, and it should be understood to include all modifications, equivalents and substitutes included in the spirit and scope of the present invention. In describing the present invention, if it is determined that a detailed description of a related known technology may obscure the gist of the present invention, the detailed description thereof will be omitted.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. do.

1 is a view showing an oil recovery device according to an embodiment of the present invention. For reference, in FIG. 1 , the X axis means the longitudinal direction of the tank 100 or the inner space 101 of the tank 100 , and the Y axis is the width direction of the tank 100 or the inner space 101 of the tank 100 . , and the Z axis means the vertical direction of the tank 100 or the inner space 101 of the tank 100 . And in FIG. 1 , +X denotes the front of the tank 100 or the internal space 101 of the tank 100 , and -X denotes the rear of the tank 100 or the internal space 101 .

Referring to FIG. 1 , the oil recovery device 10 separates and discharges a mixed solution (hereinafter referred to as a mixed solution) in which water and oil are mixed in an emulsion state into oil and water.

The oil recovery device 10 includes a tank 100 , a separation plate 200 , a bubble generating unit 300 , a bulkhead 400 , and a partition unit 500 .

The tank 100 provides a mixed solution in which water and oil are mixed in an emulsion state, and an internal space 101 (hereinafter referred to as an internal space 101 ) for accommodating oil and water separated from the mixed solution.

The inner space 101 has a predetermined length (or referred to as a front-back direction length).

For example, the inner space 101 may have a rectangular parallelepiped shape as shown in FIG. 1 .

In this case, assuming that the length (or the front-back direction length), the height (or the vertical direction length), and the width (or the left-right direction length) of the inner space 101 are L, H, and W, respectively, 1m ≤ L ≤ 10 m, 0.5 m ≤ H ≤ 5 m, and 0.3 m ≤ W ≤ 3 m. These values are in a range commonly used in the marine control field or the oil refining industry. For reference, the width W of the inner space 101 in FIG. 1 is not shown.

As another example, the inner space may have a columnar shape having a predetermined length (or referred to as a front-back direction length) such as a cylindrical shape.

The tank 100 is formed with a mixed solution inlet 111 through which the mixed solution is introduced, an oil outlet 113 through which the oil separated from the mixed solution is discharged, and a water outlet 115 through which the water separated from the mixed solution is discharged.

The mixed solution inlet 111 is formed at the front end of the inner space 101 .

In this case, the mixed solution inlet 111 may be formed in the lower region of the front end of the inner space 101 . In this case, the drop between the mixed solution inlet 111 and the bottom of the internal space 101 is small, so that the mixed solution flowing into the internal space 101 collides with the bottom of the internal space 101 to prevent oil emulsion from occurring .

The diameter of the mixed solution inlet 111 may be 0.1 times or more and 0.3 times or less of the height H of the inner space 101 . If the diameter of the mixed solution inlet 111 is less than 0.1H or exceeds 0.3H, oil-water separation performance, that is, oil recovery performance, is remarkably deteriorated.

The oil outlet 113 and the water outlet 115 are formed at the rear end of the inner space 101 .

In this case, the oil outlet 113 may be formed in the upper region of the rear end of the internal space 101 , and the water outlet 115 may be formed in the lower region of the rear end of the internal space 101 .

The diameter of the oil outlet 113 may be 0.01 times or more and 0.1 times or less of the height H of the inner space 101 . If the diameter of the oil outlet 113 is less than 0.01H, the oil draining performance is remarkably degraded, and if it exceeds 0.1H, the amount of oil discharged is significantly increased. There is a problem of significantly lowering the oil receiving capacity.

And the diameter of the water outlet 115 may be 0.1 times or more and 0.3 times or less of the height H of the inner space 101 . If the diameter of the water outlet 115 is less than 0.1H, the water discharge performance is significantly lowered, and when it exceeds 0.3H, the amount of discharged water is significantly increased, and the oil accumulated on the separated water is connected to the water outlet 115. The possibility of backflow into the water receiving space 105 arises.

The tank 100 may be provided with an air outlet 117 through which bubbles generated by the bubble generating unit 300 to be described later are discharged to the outside. At least one air outlet 117 may be formed in the tank 100 .

The separation plate 200 is located at the rear of the mixed solution inlet 111 of the inner space 101 . The separator 200 is in contact with the mixed solution introduced into the inner space 101, and separates the mixed solution into oil and water. The surface of the separator 200 may have lipophilicity.

FIG. 2 is an enlarged perspective view of an adjacent pair of the plurality of separators illustrated in FIG. 1 , and FIG. 3 is an enlarged view of a part of one of the plurality of separators illustrated in FIG. 1 .

1 to 3 , the oil emulsion of the mixed solution moving in contact with the lipophilic surface of the separator 200 is combined with each other on the surface of the separator 200 to generate large oil droplets. The resulting oil droplets rise by buoyancy and are separated from water. The oil droplet generated on the surface of the separator 200 rises through a through hole 201 to be described later formed in the separator 200 .

The separation plate 200 extends in the front-rear direction of the inner space 101 . And the separation plate 200 is extended in the left and right direction of the inner space (101). For reference, the longitudinal direction (or the front-back direction) and the width direction (or the left-right direction) of the separation plate 200 and the inner space 101 are considered to be the same.

The separator 200 may be disposed so that one surface faces upward and the other surface faces downward. That is, the separation plate 200 may be disposed in the inner space 101 so that one surface becomes the upper surface and the other surface becomes the lower surface.

The separation plate 200 is formed with a plurality of through-holes 201 penetrating vertically. The oil emulsion or oil droplets moving along the lower surface of the separator 200 may move upward of the separator 200 through the through hole 201 .

The bubble generating unit 300 generates bubbles under the separating plate 200 .

For example, the bubble generator 300 may include a compressor 310 and a chamber 330 .

Compressor 310 generates compressed air.

The chamber 330 is connected to the compressor 310 and is formed at the bottom of the inner space 101 . The chamber 330 is located below the separation plate 200 .

A plurality of air holes may be formed on the upper plate of the chamber 330 . For example, the upper plate of the chamber 330 may have a lattice structure.

The compressed air supplied to the compressor 310 flows into the chamber 330 and rises through the air hole formed in the upper plate of the chamber 330 .

When the bubbles generated in the bubble generating unit 300 rise toward the separating plate 200 , the oil emulsion passing below the separating plate 200 is attached to the bubbles by the surface tension of the bubbles and rises. The oil emulsions adhering to the bubbles merge with each other to produce oil droplets.

And the oil emulsion or oil droplet attached to the bubble rises through the through hole 201 formed in the separator 200 .

In addition to the role of raising the oil emulsion or oil droplets, the bubbles generated in the bubble generating unit 300 may prevent the through-hole 201 from being blocked by oil droplets or the like.

The separator 200 may be provided in plurality.

The plurality of separation plates 200 may be vertically spaced apart from each other.

In this case, the amount of the mixed solution moving in contact with the surfaces of the plurality of separation plates 200 is increased, so that oil and water can be effectively separated.

In the present embodiment, the separator 200 may have a wavy structure oscillating up and down. That is, the separation plate 200 has a structure in which crests and valleys are sequentially repeated while going from the front to the rear. The bottom portion of the separator 200 has a structure concave upward when viewed from below. Bubbles rising below the separator plate 200 can easily collect into the upwardly concave ridge.

In another embodiment, although not shown, the separator may have a flat plate structure other than the corrugated structure shown in FIGS. 1 to 3 .

The plurality of through-holes 201 may be dispersedly disposed in the crests and valleys of the corrugated structure of the separator 200 as shown in FIGS. 1 to 3 . In addition, a plurality of through-holes 201 formed in the crests and valleys of the separator 200 may be disposed to be spaced apart from each other in the width direction of the separator 200 as shown in FIG. 2 .

When the plurality of separator plates 200 having a corrugated structure are disposed to be vertically spaced apart from each other as described above, the bubbles generated under the separator plates 200 are easily collected on the floor of the separator plates 200, and the bubbles The attached oil emulsion merges with each other at the bottom of the separator plates 200 to generate large oil droplets, and the generated oil droplets pass through the separator plates 200 sequentially and merge to produce larger oil droplets. can

The height (relative to the bottom of the inner space 101) of the upper end of the uppermost separator 200 among the plurality of separators 200, that is, the vertical distance between the upper end of the uppermost separator 200 and the bottom of the inner space 101 The height H of the inner space 101 may be 0.6 times or more and 0.8 times or less. If the vertical distance between the top of the uppermost separator 200 and the bottom of the inner space 101 is less than 0.6H, the arrangement area of the separators 200 in contact with the mixed solution is relatively small, so that the oil separation efficiency is significantly reduced, and the uppermost layer When the vertical distance between the upper end of the separator 200 and the bottom of the inner space 101 exceeds 0.8H, the space in which the oil can be accumulated above the uppermost separator 200 is relatively small, so that the oil recovery rate is significantly reduced. can fall

The length (ie, the length in the front-rear direction) of the separator 200 may be 0.1 times or more and 0.6 times or less of the length L of the inner space 101 . If the length of the separator 200 is less than 0.1L, the oil separation efficiency is significantly reduced, and if it exceeds 0.6L, the space in which the oil can be accumulated in the rear of the separator 200 is relatively small, and the oil recovery rate may be significantly reduced. have.

The height (relative to the bottom of the internal space 101) of the top plate of the chamber 330 of the bubble generating unit 300, that is, the vertical distance between the top plate of the chamber 330 and the bottom of the internal space 101 is the internal space 101 ) may be 0.01 times or more and 0.1 times or less of the height (H). If the vertical distance between the upper plate of the chamber 330 and the bottom of the inner space 101 is less than 0.01H, the air bubbles are not uniformly applied and are driven in a specific direction, and the oil recovery rate is significantly reduced, and when it exceeds 0.1H, the chamber 330 ) above the space for arranging the separator 200, that is, the space in which the oil in the emulsion state can be combined through the separator 200 is reduced, so that the oil recovery rate is remarkably reduced.

The spacing between the separation plates 200 may be 0.01 times or more and 0.1 times or less of the height H of the inner space 101 . If the spacing between the separator plates 200 is less than 0.01H, the flow rate of the mixed solution passing between the separator plates 200 is reduced to significantly increase the time of the oil separation process, and the spacing between the separator plates 200 is 0.1H When it exceeds, the flow rate of the mixed solution passing between the separation plates 200 increases, thereby significantly reducing the oil separation efficiency.

An interval between the through holes 201 in the width direction of the separation plate 200 may be 0.001 times or more and 0.1 times or less of the width W of the inner space 101 . When the distance between the through-holes 201 in the width direction of the separator 200 is less than 0.001 W or more than 0.1 W, the oil separation efficiency is reduced.

The diameter of the through hole 201 may be 0.01 times or more and 0.1 times or less of the height H of the inner space 101 . If the diameter of the through hole 201 is less than 0.01H or exceeds 0.1H, the oil separation efficiency is reduced.

In the corrugated structure of the separator 200 , the horizontal distance in the front-rear direction between the crest and the valley may be 0.005 times or more and 0.25 times or less of the length L of the internal space 101 . If the horizontal distance between the ridge and the trough in the front-rear direction is less than 0.005L or exceeds 0.25L, the oil separation efficiency will decrease.

The diameter of the bubble generated under the separator 200 may be 100 μm or more and 3 mm or less. If the bubble diameter is less than 100 μm, the buoyancy force is not sufficient to pull up the oil droplets generated by merging the oil emulsion, and if the bubble diameter exceeds 3 mm, the through hole 201 formed in the separator 200 may be blocked. am.

Referring to FIG. 1 , the oil recovery device 10 according to the present embodiment may further include a partition wall 400 .

The partition wall 400 is disposed between the mixed solution inlet 111 and the separation plate 200 .

The partition wall 400 has a plate shape and extends in the vertical direction of the inner space 101 and extends in the left and right directions.

The partition wall 400 may be disposed perpendicularly or obliquely to the front-rear direction of the internal space 101 .

The partition wall 400 has a lower end in contact with the floor of the inner space 101 and an upper end spaced apart from the ceiling of the inner space 101 .

The mixed solution introduced through the mixed solution inlet 111 is blocked by the partition wall 400 and cannot directly move toward the separation plate 200 , but moves toward the separation plate 200 beyond the partition wall 400 . At this time, the mixed solution moves toward the separation plate 200 through a gap between the upper end of the partition wall 400 and the ceiling of the inner space 101 .

The partition wall 400 delays the time that the mixed solution introduced through the mixed solution inlet 111 moves toward the separating plate 200 and prevents a large amount of the mixed solution from moving directly to the separating plate 200 in a short time. is stably and uniformly supplied to the separator 200 .

The partition wall 400 may be located in a range of 0.05 times or more and 0.2 times or less of the length L of the internal space 101 from the front end of the internal space 101 . When the partition wall 400 is located in the range of less than 0.05L from the front end of the internal space 101, the space in which the introduced mixed solution is accumulated is insufficient, and the partition wall 400 passes too quickly, and the partition wall 400 is the internal space. If it is located in a range exceeding 0.2L from the front end of 101, there is insufficient space for interaction with the separation plate 200 and air bubbles at the rear, and the oil recovery rate is lowered.

The height of the partition wall 400 (meaning the height of the internal space 101 with respect to the floor) may be 0.1 times or more and 0.5 times or less of the height H of the internal space 101 . If the height of the barrier rib 400 is less than 0.1H, the effect of delaying the flow of the mixed solution by the barrier rib 400 is insignificant.

Referring to FIG. 1 , the oil recovery device 10 according to the present embodiment may further include a partition unit 500 .

The partition unit 500 is disposed at the rear of the separation plate 200 , and divides a part of the internal space 101 into an oil receiving space 103 and a water receiving space 105 .

The oil receiving space 103 receives the oil separated from the mixed solution and is connected to the oil outlet 113 .

The water receiving space 105 introduces water separated from the mixed solution and is connected to the water outlet 115 .

The oil accommodating space 103 and the water accommodating space 105 may be vertically adjacent to each other.

The partition unit 500 may include a first partition member 510 and a second partition member 530 .

The first partition member 510 is disposed behind the separation plate 200 .

The first partition member 510 has a plate shape and extends in the vertical direction and the left and right directions of the inner space 101 .

The first partition member 510 may be disposed perpendicularly or obliquely to the front-rear direction of the inner space 101 .

The lower end of the first partition member 510 is spaced apart from the bottom of the inner space 101 and the upper end is spaced apart from the ceiling of the inner space 101 . The distance between the lower end of the first partition member 510 and the bottom of the inner space 101 and the distance between the upper end of the first partition member 510 and the ceiling of the inner space 101 may be the same.

In the present embodiment, the first partition member 510 functions as a front partition that defines an oil receiving space 103 and a water receiving space 105 to be described later.

The second partition member 530 extends rearward from the rear surface of the first partition member 510 .

The second partition member 530 has a plate shape and extends in the front-rear direction and the left-right direction of the inner space 101 .

The second partition member 530 may be disposed perpendicularly or obliquely to the vertical direction of the inner space 101 .

The second partition member 530 divides the upper and lower portions of the rear space of the first partition member 510 into an oil accommodating space 103 and a water accommodating space 105 , respectively. In this case, the oil accommodating space 103 and the water accommodating space 105 may be defined by the first partition member 510 , the second partition member 530 , and outer walls of the tank 100 .

The oil passed through the separation plate 200 and separated from the mixed solution passes through the gap between the upper end of the first partition member 510 and the ceiling of the inner space 101 (hereinafter referred to as the oil inlet 513 ) through the oil receiving space 103 . ) is introduced into The oil introduced into the oil receiving space 103 is discharged to the outside through the oil outlet 113 .

And when the separation plate 200 passes, the water separated from the mixed solution passes through the gap between the lower end of the first partition member 510 and the bottom of the inner space 101 (hereinafter referred to as the water inlet 515) through the water receiving space ( 105) is introduced. The water introduced into the water receiving space 105 is discharged to the outside through the water outlet 115 .

Referring to FIG. 1 , the oil recovery device 10 according to the present embodiment may further include a floating body 600 .

The floating body 600 is vertically slidably coupled to the front surface of the first partition member 510 .

For example, referring to FIG. 4 , any one of the floating body 600 and the first partition member 510 (the first partition member 510 is shown in FIG. 4 ) has a sliding groove 531 extending in the vertical direction. A sliding protrusion 601 that is inserted into the sliding groove 531 and slides is formed in the other one (shown as the floating body 600 in FIG. 4 ).

For reference, FIG. 4 is a view for explaining an example of a coupling structure between the floating body and the first partition member.

The floating body 600 may have a plate shape or a box shape.

The floating body 600 extends in an up-down direction and a left-right direction. The length in the left and right direction of the floating body 600 has a size corresponding to the length in the left and right direction of the oil inlet 513 and the water inlet 515 .

The vertical length of the floating body 600 is smaller than the vertical length of the first partition member 510 .

The floating body 600 floats over the interface between oil and water located in front of the first partition member 510 . In this case, a part of the floating body 600 is located above the interface between oil and water and the rest is located below the interface between oil and water.

For example, when the ratio of water in the mixed solution is much higher than that of oil, the thickness of the oil layer in the separated water and oil located in the space behind the separator 200 is relatively very thin compared to the water layer.

In this case, the floating body 600 is preferably formed to float across the interface between oil and water so that the vertical length of the portion spanning the water is greater than the vertical length of the portion spanning the oil.

_{At this time, the ratio of the vertical length (h w} ) of the part submerged in water of the float 600 and the vertical length (h _o ) of the part submerged in oil has a range between 8:2 and 6:4. can

In this numerical range, it is assumed that the density of oil is 870 kg/m3, which is the density of crude oil, the density of water is 1000 kg/m3, and the density of the floating body 600 is 946 kg/m 3 or more and 972 kg/m 3 or less. can be calculated.

If the proportion of the floating body 600 submerged in oil is less than 20%, the risk of water overflowing into the oil inlet 513 is increased, and conversely, if it is more than 40%, the floating body 600 is the water inlet 515. Alternatively, a situation in which the oil inlet 513 is continuously closed may occur, so that the oil recovery speed may be significantly reduced.

The floating body 600 is the oil inlet 513 according to the height of the interface between the oil and water with respect to the bottom of the internal space 101, or in other words, the vertical distance between the bottom of the internal space 101 and the interface (oil and water). Alternatively, the water inlet 515 may be completely or partially closed.

For example, referring to FIG. 5, when the interface between oil and water is close to the bottom of the internal space 101, the lower end of the floating body 600 floating across the interface between oil and water is higher than the upper end of the water inlet 515. 101) can be located close to the bottom. For reference, FIG. 5 is a view for explaining an operation example of the floating body.

In this case, the floating body 600 partially closes the water inlet 515 , and water is introduced into the water receiving space 105 through the partially closed water inlet 515 . In this case, the oil will build up on top of the water.

For example, referring to FIG. 6 , when the interface between oil and water is close to the ceiling of the internal space 101, the upper end of the floating body 600 floating across the interface between oil and water is higher than the lower end of the oil inlet 513 in the internal space ( 101) can be located close to the ceiling. For reference, FIG. 6 is a view for explaining another operation example of the floating body.

In this case, the floating body 600 partially closes the oil inlet 513 , and oil is introduced into the oil receiving space 103 through the partially closed oil inlet 513 . In this case, water may be introduced into the water receiving space 105 through the fully opened water inlet 515 .

For example, referring to FIG. 7 , when the interface between oil and water is located in the middle region between the ceiling and the floor of the inner space 101 , the floating body 600 floating across the interface between oil and water is an oil inlet 513 and a water inlet It may not be possible to close (515). For reference, FIG. 7 is a view for explaining another operation example of the floating body.

In this case, water is introduced into the water accommodating space 105 through the water inlet 515 , and oil is accumulated on top of the water.

The floating body 600 as above floats across the interface between oil and water positioned in front of the first partition member 510 , so that the oil accumulated on the water is water regardless of the height of the interface with respect to the bottom of the inner space 101 . Intrusion into the water receiving space 105 through the inlet 515 or water located under the oil from penetrating into the oil receiving space 103 through the oil inlet 513 is prevented. Accordingly, the oil recovery performance of the oil recovery device 10 can be maximized.

The vertical distance from the bottom of the oil receiving space 103 to the lower end of the oil inlet 513 may be 0.1 times or more and 0.2 times or less of the height H of the inner space 101 . If the vertical distance from the bottom of the oil receiving space 103 to the lower end of the oil inlet 513 is less than 0.1H, there is a possibility that the floating body 600 continuously closes the oil inlet in order to prevent the inflow of water, so that the oil recovery performance can significantly decrease, and when it exceeds 0.2H, the oil receiving space becomes too large, resulting in inefficiency.

The height of the floating body 400 , the vertical distance from the lower end to the upper end of the floating body 400 expressed differently, may be 0.2 times or more and 0.4 times or less of the height H of the internal space 101 . If the height of the floating body 600 is less than 0.2H, oil overflows the floating body 600 and flows into the water inlet, or water overflows the floating body 600 and flows back into the oil inlet 513 easily, so that water or It is insufficient to act as a partition for preventing the backflow of oil, and when it exceeds 0.4H, there is a possibility that the oil inlet 513 is completely closed for a long time, which significantly reduces the oil recovery rate.

The height of the first partition member 510 , in other words, the vertical distance from the lower end to the upper end of the first partition member 510 may be 0.6 times or more and 0.8 times or less of the height H of the internal space 101 . The above numerical range was determined by whether the first partition member 510 can completely open and close the oil inlet 513 and the water inlet 515 by the floating body, and was derived through experiments or numerical analysis.

In the above, although embodiments of the present invention have been described, those of ordinary skill in the art can add, change, delete or add components within the scope that does not depart from the spirit of the present invention described in the claims. The present invention may be variously modified and changed by, etc., and this will also be included within the scope of the present invention.

10: oil recovery device
100 : tank
101: inner space
103: oil receiving space
105: water receiving space
111: mixed solution inlet
113: oil outlet
115: water outlet
117: air outlet
200: separator
201: through hole
300: bubble generating unit
310: Compressor
330: chamber
400: bulkhead
500: compartment
510: first partition member
530: second partition member
600: floating body

Claims (7)

An oil recovery device that separates oil and water and discharges a mixed solution in which water and oil are mixed in an emulsion state,
An internal space for accommodating the mixed solution and oil and water separated from the mixed solution is provided, a mixed solution inlet through which the mixed solution flows is formed at the front end of the internal space, and a mixed solution inlet is formed at the rear end of the internal space to be separated from the mixed solution a tank in which oil and water outlets and oil outlets are respectively discharged;
a separation plate located at the rear of the mixed solution inlet in the inner space, one side facing up and the other side facing down, a plurality of through holes penetrating vertically and having a lipophilic surface; and
An oil recovery device comprising a bubble generating unit for generating bubbles under the separation plate. According to claim 1,
The separator is provided in plurality,
The plurality of separation plates are vertically spaced apart from each other. According to claim 1,
The separation plate has a corrugated structure oscillating up and down,
The plurality of through-holes are dispersedly disposed in crests and troughs of the corrugated structure. According to claim 1,
and a partition wall disposed between the mixed solution inlet and the separation plate, a lower end in contact with the floor of the inner space and a partition wall at an upper end spaced apart from the ceiling of the inner space. According to claim 1,
A compartment which is disposed at the rear of the separation plate and divides into an oil receiving space through which the oil separated from the mixed solution flows in and connected to the oil outlet, and a water receiving space through which the water separated from the mixed solution flows in and connected to the water outlet. Further comprising a portion, the oil recovery device. 6. The method of claim 5,
The compartment is
a first partition member disposed behind the separation plate, the lower end being spaced apart from the bottom of the inner space and the upper end being spaced apart from the ceiling of the inner space; and
and a second partition member extending rearward from the rear surface of the first partition member and partitioning upper and lower portions of the rear space of the first partition member into the oil receiving space and the water receiving space, respectively. 7. The method of claim 6,
The first partition member is slidably coupled up and down to the front surface of the first partition member, and floats over the interface between oil and water positioned in front of the first partition member, and according to the height of the interface with respect to the floor of the internal space, the second partition The oil recovery device further comprising: a floating body configured to close an oil inlet formed between an upper end of the first partition member and the ceiling of the inner space or a water inlet formed between a lower end of the first partition member and a bottom of the inner space.

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