KR910001890B1 - Oil and water seperating method and apparatus - Google Patents

Abstract

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Description

Oil-water separation method and apparatus

1 is a front cross-sectional view.

2 is a cross-sectional view taken along the line II-II of FIG.

3 is a cross-sectional view taken along the line III-III of FIG.

4 is a cross-sectional view of another embodiment of an oil incorporation unit constituted by a porous membrane.

* Explanation of symbols for the main parts of the drawings

1: container la: upper container

1b: lower container 2: outlet pipe

3: gravity separation chamber 4: cylindrical shield

5: raw water supply pipe 9: fibrous oil incorporation layer

11 oil fractionation 12 treated water outlet pipe

13: porous membrane

The present invention relates to a method and a device for separating water or seawater (hereinafter referred to simply as raw water) containing oil such as sewage and the like accumulated on the sole of a ship into water and oil.

Generally, the separation of oil water includes: ① gravity separation method using the specific gravity difference between oil and water, ② oil granulation method for coarse granulation of oil, and ③ adsorption collection method for adsorption and collection of oil to layers such as activated carbon or fiber. However, the conventional method has been implemented by a suitable combination of these separation methods.

For example, Japanese Patent Application Laid-Open No. 58-41887 or Japanese Patent Application No. 55-16687 proposes to form a combination of three characters of an oil-incorporated fiber layer gravity separation chamber and an adsorption trapping fiber layer.

However, this prior art separation method, after separating the oil by passing the raw water through the gravity separation chamber and the oil-incorporated fiber layer, and finally in the adsorption trapping fiber layer, the micro-droplets still remaining in the raw water. Adsorption trapping in the tissue of the adsorption trapping fiber layer, the oil is accumulated in the tissue of the adsorption trapping fiber layer, and when foreign matter aggregates in the mesh of the adsorption trapping fiber layer, raw water passes through the adsorption trapping fiber layer. In addition to the rapid increase in the passage resistance, if the amount of oil accumulated in the tissue is over a certain amount, the micro-droplets in the raw water pass through the adsorption trapping fiber layer together with the treated water without being trapped in the trapping trapping fiber layer. It is impossible to operate for a long period of time due to efficiency, and the oil trapped in the tissue of the adsorption trapping fiber layer There is a problem in that a regeneration operation for washing and removing the powder must be frequently performed. In particular, this problem was remarkable in the case of raw water having a high oil concentration or raw water containing a high viscosity oil such as C heavy oil.

The present invention provides a separation method and a separation device capable of continuously operating for a long time with high separation efficiency.

Therefore, in the present invention, raw water, such as oil-containing water or seawater, is first removed from the coarse ruins in the gravity separation chamber), and then passed through a fibrous oil-coated layer to make crude oil. Separation is carried out, and then a porous membrane composed of a material having water-repellent and oil-repellent properties is passed through to allow for precise separation of the running water.

The raw water is separated in the coarse droplets contained in the raw water in the gravity separation chamber, and the next time, when passing through the fibrous oil incorporation layer, relatively small remnants which are not separated by the gravity separation coagulate and grow into coarse oil. Pass through the porous membrane. Since the porous membrane is composed of a material having oil-repellent properties, the micro-oil droplets that cannot be separated in the gravity separation and fibrous oil incorporation layer are oil-repellent that the porous membrane has when passing through the porous membrane. As a function of, it can coagulate on the surface of the porous membrane and grow coarsely, allowing oil to be separated.

As a result, the porous membrane for finally separating the micro-residue still remaining in the raw water accumulates oil in the same tissue as the adsorption trapping fiber layer of the prior art in coagulating oil and oil in the coagulation of oil due to its oil-repellent property. Since the passage resistance of raw water to the porous membrane does not increase rapidly with the passage of time, the porous membrane has oil repellent properties and water repellent properties. Swelling can be prevented with infiltration.

Example

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, the present invention will be described with reference to the drawings. In the drawings, 1 denotes a sealed container, and the container 1 detaches the upper container a and the lower container 1b from the flange part 1c. The outlet pipe 2 is opened in the government in the upper container la.

3 is an annular gravity separation chamber formed outside the cylindrical shield 4 by providing a cylindrical shield 4 in the upper container la, and in the gravity separation chamber 3, a supply pipe for raw water ( At the same time as 5) is opened, a shielding plate 7 constituting between the through hole 6 laid in the cylindrical shield 4 and the raw water supply pipe 5 is provided, and the raw water supply pipe ( The raw water introduced from 5) flows in the gravity separation chamber 3 in the circumferential direction, and is then introduced into the cylindrical shield 4 through the through hole 6. In addition, in the gravity separation chamber 3, a barrier plate 8 is provided to flow over the raw water flowing in the gravity separation chamber 3.

The upper container 1a is a fibrous oil-incorporated layer 9 filled with a metal fiber having a diameter of 20-70 microns in the lower portion of the gravity separation chamber ³ within a thickness of 30-100 mm with a packing density of 250-300 kg / m ³ . Install). The oil incorporation layer 9 may be made of synthetic resin fibers instead of being composed of metal fibers, or the oil incorporation layer 9 may be laminated in such a manner that the diameter of the oil infiltrate the upper surface of the thick one. You may make it.

In addition, in the lower container (1b), the oil immersion unit attached to the detachable material with respect to the shielding plate 10 inserted into the detachable material (1c) of the junction between the upper container (la) and the lower container (1b) ( 11), the treated water outlet pipe 12 is connected to the bottom of the lower container 1b.

The oil injecting unit 11 is formed of a porous inner membrane 14 made of a material having water- and oil-repellent properties such as polystyrene terephthalate and a supporting inner cylinder 14 made of a porous plate such as a gold mesh and the supporting inner cylinder ( 14 is formed in the shape of a cylindrical cartridge by inserting it between the support outer cylinder 15 of a porous plate such as a gold mesh inserted to the outside, and the support inner cylinder 14 and the support outer cylinder 15 are placed on the ceiling surface. The outlet hole 16 is detachably fastened as a stay bolt 19 to the header 18 having the inlet hole 19 of raw water on the side, and the header 18 is attached to the shield plate 10. Is attached to and detached from the bolt 20 as a bolt 20. In this case, in order to increase the surface area of the porous membrane 13 in the oil incorporation unit 11, as described above, a plurality of oil incorporation units 11 formed in a cylindrical cartridge shape are provided, or the black porous membrane 13 is formed. ) Can be bent into a zigzag shape as shown in FIG.

In addition, when the oil level detection sensor 21 detects the oil level by installing the oil level detection sensor 21 in the upper portion of the upper container la, the solenoid valve 22 in the outlet pipe 2 is configured to open. One of which connects the outlet port 23 provided below the fibrous oil incorporation layer 9 to the outlet port 2 through a pipe line 26 having a valve 24 and a check valve 25; An outlet pipe 28 having a valve 27 is attached to an upper portion of the lower container 1b, and a sludge outlet pipe 30 having a valve 29 is provided at a bottom of the gravity separation chamber 3, respectively.

Therefore, the raw water introduced into the gravity separation chamber 3 from the raw water supply pipe 5 is sedimented and separated in the bottom of the gravity separation chamber 3 when the flow flows in the gravity separation chamber 3 in the circumferential direction to settle the valve. Coarse remains in one or the raw water which are periodically discharged out of the air from the sludge outlet pipe 30 to which the 29 is attached are separated and floated toward the government in the upper container la.

In this way, the raw water from which the sludge and the coarse soil are separated in the gravity separation chamber 3 flows into the cylindrical shield 4 through the through-hole 6 installed in the cylindrical shield 4 and enters into the cylindrical shield 4. At the time of descent, the remains are separated to the government in the upper container (la).

Oil raised to the government in the upper vessel 1a is discharged to the outside by the solenoid valve 22 in the outlet pipe 2 being opened by the oil level detection sensor 21 with the detection of the oil level.

On the other hand, when the raw water descending in the cylindrical shield 4 passes through the fibrous oil incorporation layer 9 provided below the gravity separation chamber 3, the gravity shield chamber 3 and the cylindrical shield 4 Remains that are inseparable within the c) are separated from each other toward the government in the upper container la by agglomerating and growing coarsely.

The raw water after passing through the fibrous oil incorporation layer 9 flows into the porous membrane 13 in the oil incorporation section 11 through the inflow hole 17 in the header 18 to form a porous membrane ( 13) pass. At this time, the porous membrane 13 is composed of a material having oil-repellent properties, so that the porous membrane 13 can be separated in the gravity separation chamber 3, in the cylindrical shield 4, and in the fibrous oil incorporation layer 9. The non-small oil droplet is the action of oil repelling property of the porous membrane when passing through the porous membrane 13, and coagulates on the surface of the porous membrane 13, grows coarsely, and floats to separate the oil. After the water is separated, the treated water is discharged to the outside from the outlet pipe 12, and the coarse remains on the inner surface of the porous membrane 13 passes through the outlet hole 16 in the header 18. And the coarse remains on the outer surface of the porous membrane 13 rises toward the lower surface of the shielding plate 10, and then periodically exits from the outlet pipe 28 to which the valve 27 is attached. To be discharged.

In addition, the oil remaining on the lower side of the fibrous oil incorporation layer 9 is discharged to the outside from the outlet pipe 2 through the pipeline 26 by periodically opening the valve 24, in this case The check valve 25 provided in the conduit 26 is left in the upper part of the upper vessel la when the valve 24 is opened when the solenoid valve 22 in the outlet pipe 2 is closed. The oil flows into the lower surface of the oil coarse blending layer 9 to prevent this.

In addition, the oil concentration (ppm) and the fiber at the A portion before entering the fibrous oil-coated layer 9 by performing a separation test on the water mixed with C heavy oil and the water mixed with light oil using the above apparatus. The oil concentration (ppm) at the B points after passing through the oil coagulation layer 9 and the oil concentration (ppm) at the C points after passing the porous membrane 13 in the oil coagulation unit 11 respectively. The measurement results are shown in the following table.

As described above, according to the present invention, the oil content in raw water is first separated by gravity separation method, and then by the oil-incorporated layer of fibrous material. By using a porous membrane constituted as a material, it is possible to avoid the rapid increase in the passage resistance of raw water to the porous membrane with the passage of time, and to prevent swelling due to the penetration of water and oil in the porous membrane. The durability can be high, the separation efficiency can be improved, and the operation by high separation efficiency can be maintained for a long time, and especially the diesel fuel containing high viscosity oils such as C heavy oil, etc. When is high, a remarkable effect can be exhibited.

Claims (2)

Raw water, such as oil-containing water or seawater, is first removed in the gravity separation chamber, and then crude oil separation is carried out through a fibrous oil incorporation layer, and a porous material composed of water-repellent and oil-repellent properties. Oil-water separation method characterized in that the flow of water through the membrane to separate the flow. In the container having the outlet of the treated water at the bottom, a gravity separation chamber in which raw water first flows into the upper layer, an oil-infused layer composed of fibers of metal or synthetic resin in the middle layer, and a water-repellent and oil-repellent property in the lower layer. The oil-water separation apparatus which opens the outlet port in the upper part of the said gravity separation chamber, respectively, which respectively installs the oil-implantation part which consists of a porous film of Claims.

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