KR20180106386A - Volumetric pump for oil-water separating and oil-water separating method using the same - Google Patents

Abstract

The present invention relates to a volumetric pump for oil-water separation and to an oil-water separating method using the same, in which the oil-water separation pump for pumping a mixed fluid of water and oil is operated at a low speed to prevent oil-water from mixing due to vortexing of the mixed fluid pumped into an oil water separator, and reduce a separation time of the mixed fluid, so that a large amount of mixed fluid of water and oil can be treated within a short time.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to an oil-water separating pump and an oil-

More particularly, the present invention relates to a metering pump for metering water and a method for separating water and oil from the oil and water, The present invention relates to a metering pump for metering water, which operates at a low speed so that the metering pump can be separated without mixing.

There are many ways to treat oil flowing out in the event of oil pollution accident. However, most of the conventional oil water separator uses gravity separation method and filter filtration method.

The filter filtration method is not suitable for the recovery of oil because the filtration of oil is to discharge the water and the pores of the filter are clogged with oil and must be frequently replaced or cleaned.

The gravity separation method separates the oil and water by gravity and discharges water satisfying the oil discharge regulation value. In order to separate the oil and water from each other, the gravity separation method requires a long time for separation. In order to treat a large amount of mixed fluid of water and oil, a large number of oil and water separation tanks are required.

On the other hand, a method of supplying a mixed fluid of a large amount of water and oil to the oil water separator, separating it into a water layer and a oil layer in the oil water separator, and discharging the water and storing only oil in the oil storage tank may be considered.

However, even in such an oil water separator, since the oil pump for pumping the mixed fluid to the oil separator rotates at a high speed, mixing of water and oil occurs due to the swirling flow of the mixed fluid, and thus it takes a long time to separate the water layer and the oil layer .

It is an object of the present invention to reduce the separation time of the mixed fluid by operating the pump for pumping water, which pumps the mixed fluid of water and oil with the oil water separator, at a low speed to prevent mixing of the mixed fluid pumped into the oil water separator, And to provide a metering pump for metering water which can treat a large amount of mixed fluid of water and oil within a short time, and a method for separating water using the same.

The metering pump for metering water according to the present invention is a metering pump for metering water used for separating water and oil from a mixed fluid of oil and water, wherein the mixed fluid of oil and water is pumped into the oil separator by the metering pump for metering water , Wherein the rotation speed of the metering pump for water splitting is 110 to 900 rpm.

At this time, it is more preferable that the rotating speed of the metering pump for water-oil separation is 160-180 rpm.

The oil-water separation method using the metering pump for metering water according to the present invention comprises: a mixed fluid pumping step of pumping a mixed fluid of oil and water into a water-oil separator using a metering pump for metering water; A mixed fluid separation step of separating water and oil from the pumped mixed fluid; Storing the separated oil temporarily, and then transferring the separated oil to the oil storage tank; And a water discharging step of discharging the separated water to the outside, wherein the mixed fluid pumping step is a step of operating the rotating speed of the metering pump for flowing water at a flow rate of 110 to 900 rpm .

In this case, it is more preferable that the mixed fluid pumping step operates the rotating speed of the metering pump for water-oil separation at 160 to 180 rpm.

According to the present invention, there is provided a metering pump for metering water and a water separation method using the same, wherein the water separation pump for pumping the mixed fluid of water and oil to the water separation separator is operated as low- So that the separation time of the mixed fluid can be reduced and the mixed fluid of a large amount of water and oil can be treated within a short time.

1 is a perspective view of a water-oil separator using a metering pump for water-diluting according to the present invention.
2 is a plan view of an oil-water separator using a metering pump for water-diluting according to the present invention.
3 is a side view of a water-oil separator using a metering pump for water-diluting according to the present invention.
4 is a cross-sectional view showing an internal structure of a first separator of a water-oil separator using a metering pump for water-diluting according to the present invention.
5 is a cross-sectional view showing the internal structure of the second separator of the oil-water separator using the metering pump for oil-water separation according to the present invention.
FIG. 6 is a flowchart showing a process of a water separation method using a metering pump for water splitting according to the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, a metering pump for metering water according to the present invention and a water separation method using the same will be described with reference to the accompanying drawings.

FIG. 1 is a perspective view of an oil water separator using a metering pump for metering water according to the present invention, FIG. 2 is a plan view of a water separator using a metering pump for metering water according to the present invention, and FIG. FIG. 4 is a transverse sectional view showing the internal structure of the first separator of the oil separator using the metering pump for oil-water separation according to the present invention, and FIG. 5 is a cross-sectional view of the metering pump for oil- Sectional view showing the internal structure of the second separator of the used oil separator.

1 to 3, the oil separator using the metering pump for metering water according to the present invention comprises an inlet 10, a metering pump 20 for water distillation, a venturi 30, The first separation plate 50, the second separation unit 60, the second separation plate 70, the transfer unit 80, the water separation tank 90, the oil pump 100, the oil storage tank (not shown) 110).

A mixed fluid of oil and water flows into the inflow section (10). The inflow section 10 has a wide venturi shape so that a mixed fluid of oil and water can be introduced into a wide area.

The metering pump 20 for pumping water serves to pump the mixed fluid introduced from the inlet 10.

At this time, it is preferable that the rotation speed of the metering pump for oil-water separation operation is 110 to 900 rpm, and more preferably 160 to 180 rpm.

The conventional pump has a problem in that the mixing of water and oil takes place by pumping the mixed fluid of water and oil to the oil water separator while rotating at a high speed of 1750 rpm or more in the conventional pump, . However, when the rotation speed of the metering pump for water distillation is operated at a low speed of 110 to 900 rpm, particularly 160 to 180 rpm, as in the present invention, when the mixed fluid flows into the oil water separator, So that it is possible to further reduce the time required for separation of water and oil.

The venturi unit 30 serves to flow the mixed fluid pumped by the metering pump 20 for reducing the water content and reduce the flow rate of the introduced mixed fluid so as to form a laminar flow.

The flow rate of the mixed fluid pumped by the metering pump 20 for metering water is further reduced by the venturi unit 30 so that the pumped mixed fluid is laminar and the water layer and the oil layer can be separated.

The first separator 40 is connected to the end of the venturi 30 and communicates with the first separator 40. The first separator 40 passes the mixed fluid having a reduced flow rate and separates the oil and the water.

4, the first separator 50 is disposed at a discharge-side end portion of the first separator 40, and the first separator 40 is connected to the first oil-flow portion 41 ) And a first water flow portion (42), the upper portion being parallel to the flow direction of the fluid so that the oil layer and the water layer are separated from each other, the lower end being in contact with the lower end wall of the first separation portion (40) Is formed so as to be in contact with the side wall of the side wall 40 and has a "? &Quot; shape.

The upper part of the first separator plate 50 separates the oil layer and the water layer and the oil layer flows to the upper part of the first separator plate 50, .

The first separator plate 50 may be divided into a plurality of portions so that a portion where the water layer flows may be divided into a plurality of portions. It is preferable that the number of the first separator plates 50 is three.

The reason why the first separator plates 50 are provided in plurality is that only the layer in which the oil layer and the water layer coexist is filtered by a bag filter to be described later. Only the water layer exists below the layer where the oil layer and the water layer coexist.

The second separator 60 communicates with the first oil-flow portion 41 partitioned by the first separator plate 50, and the first-separated oil passage passes through the second separator 60 and separates the oil and water .

5, the second separator 70 is disposed at a discharge-side end portion of the second separator 60, and the second separator 60 is connected to the second oil-flow portion 61, And a second water-flow portion (62), the upper portion of which is parallel to the flow direction of the fluid so that the oil layer and the water layer are separated from each other, the lower end thereof is in contact with the lower end wall of the second separation portion (60) (60) so as to be in contact with the side wall. Since the second separator 70 is the same as the first separator 50, its explanation is omitted.

The transfer unit 80 is connected to the second oil flow unit 61 partitioned by the second separation plate 70, and the separated oil is transferred.

The water retention tank (90) communicates with the transfer unit (80), and the transferred oil is temporarily stored.

The oil pump 100 functions to pump the oil temporarily stored in the oil separator 90.

The oil pumped by the oil pump 100 flows into the oil storage tank 110.

In the oil water separator of the present invention having the above-described structure, the flow rate of the introduced mixed fluid is reduced to form laminar flows, and the oil and the oil are separated into the water layer and the oil layer, so that the oil is stored in the oil storage tank. A large amount of mixed fluid of water and oil can be treated.

The present invention further includes a baffle plate (43) inside the first separator (40) to facilitate the separation of the water layer and the oil layer from the mixed fluid whose flow rate is reduced by the venturi (30).

The baffle plate 43 is disposed inside the first separator 40 and is provided at a front end of the first separator plate 50 and perpendicular to the flow direction of the fluid so as to form a zigzag flow path in the right- And a plurality thereof.

In the present invention, it is preferable that the terminal area of the first separator 40, the second separator 60, and the transfer part 80 gradually decreases from the inflow part to the discharge part.

When the terminal area of the first separator 40, the second separator 60, and the transfer unit 80 becomes smaller, the fluid is discharged while maintaining the laminar flow.

It is preferable that the fluid channel including the first separator 40, the second separator 60, and the transfer unit 80 has an S shape.

In order to reduce the flow rate of the fluid when the fluid channel becomes S-shaped as described above, the total length of the first separator 40, the second separator 60, and the transfer unit 80 is reduced, .

In addition, the present invention provides first, second, and third bags 121, 122, and 123 and first, second, and third discharge pumps 131, 132, and 133 for discharging water separated from the oil.

The first bag filter 121 is installed outside the first separator 40 and communicates with the first water flow portion 42 and is connected to the first water flow portion 42 through the oil remaining from the water discharged to the outside of the first water flow portion 42 .

The first discharge pump 131 discharges the oil-removed water to the outside by the first bag filter 121.

The second bag filter 122 is provided outside the second separator 60 and communicates with the second water flow unit 62 and is connected to the second water flow unit 62, .

The second discharge pump 132 discharges the oil-removed water to the outside by the second bag filter 122.

The third bag filter 123 is installed on the lower outer side of the water separator tank 90 and communicates with the water tank separator 90 to remove residual oil from the remaining water in the water tank separator 90 .

The third discharge pump 133 discharges the oil-removed water to the outside by the third bag filter 123.

Thus, the present invention separates the water layer and the oil layer, and the separated water is filtered by the bag filter and discharged to the outside, so that a large amount of mixed fluid of water and oil can be treated.

In addition, the present invention is provided inside the first separating part (40) between the first separating plate (50) and the baffle plate (43) so that the front is low and the rear is high so as to assist separation of the water layer and the oil layer It is preferable to further include an inclined plate 44 which is inclined.

FIG. 6 is a flowchart showing a process of a water separation method using a metering pump for water splitting according to the present invention.

Referring to FIG. 6, the oil separation method using the metering pump for metering water according to the present invention includes a mixed fluid pumping step S610, a mixed fluid separation step S620, a oil transfer step S630, and a water discharge step S640. Respectively.

 In the mixed fluid pumping step (S610), a mixed fluid of oil and water is pumped into the oil water separator by using a metering pump for oil water separation, and a mixed fluid separating step (S620) separates water and oil from the pumped mixed fluid.

In the oil transfer step S630, the separated oil is temporarily stored and then transferred to the oil storage tank. In the water discharge step S640, the oil separated water is discharged to the outside.

Meanwhile, in the mixed fluid pumping step (S610), it is preferable that the rotating speed of the metering pump for flowing water is operated at 110 to 900 rpm, particularly 160 to 180 rpm.

When the rotation speed of the metering pump for oil-water separation is operated at a low speed of 110 to 900 rpm, particularly 160 to 180 rpm, mixing of water and oil is minimized in the course of flowing the mixed fluid into the oil water separator So that it is possible to further reduce the time required for separation of water and oil.

While the present invention has been described in connection with what is presently considered to be practical exemplary embodiments, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, It will be understood by those skilled in the art that the present invention may be embodied in other specific forms without departing from the spirit or essential characteristics thereof. It is therefore to be understood that the above-described embodiments are illustrative in all aspects and not restrictive.

10: inflow section 20: metering pump for water separation
30: Venturi unit 40: First separation unit
41: first oil flow section 42: first oil flow section
43: baffle plate 44: swash plate
50: first separator plate 60: second separator plate
61: second oil flow section 62: second oil flow section
70: second separator 80: conveying part
90: Oil separation tank 100: Oil pump
110: Oil storage tank 121, 122, 123: First, second and third bag filters
131, 132, 133: first, second and third discharge pumps

Claims (4)

1. A metering pump for metering water used for separating water and oil from a mixed fluid of oil and water,
Wherein the mixed fluid of the oil and water is pumped into the oil water separator by the metering pump for metering water, wherein the rotational speed of the metering pump for metering water is 110 to 900 rpm.
The method according to claim 1,
Characterized in that the rotation speed of the metering pump for metering water is in the range of 160 to 180 mPa (rpm).
In the oil-water separation method,
A mixed fluid pumping step of pumping a mixed fluid of oil and water into the oil water separator by using a metering pump for oil water separation;
A mixed fluid separation step of separating water and oil from the pumped mixed fluid;
Storing the separated oil temporarily, and then transferring the separated oil to the oil storage tank; And
And a water discharging step of discharging the separated water to the outside,
The mixed fluid pumping step
And operating the rotating speed of the metering pump for flowing water at a flow rate of 110 to 900 mPa (rpm).
4. The method of claim 3, wherein pumping the mixed fluid comprises:
And operating the rotating speed of the metering pump for oil-water separation at 160 to 180 rpm.

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