KR102101594B1 - Apparatus for separating oil-water from oil sand plant - Google Patents

Abstract

The present invention relates to an apparatus for separating oil and water in an oil sand plant, which separately separates traces of oil, water, and impurities by a plurality of stages of circular separation plates while allowing the traces of oil, which is contained in separation water separated and discharged from bitumen in a bitumen separation apparatus of the oil sand plant, to float by microbubbles, collects the separated traces of oil as the traces of the separated oil floats upwardly, separately discharges and reuses the water separated from the oil by layers, and sinks and discharges the impurities to remove the impurities. To this end, the apparatus for separating oil and water in an oil sand plant comprises: an inflow unit mixing the separated water generated in the process of treatment on oil sand with air to form mixed water in which microbubbles are mixed with the separated water; a separation unit separating the water, oil, and impurities included in the separated water into each component while the mixed water introduced through the inflow unit is received and lifted; an oil collection unit collecting the oil separated by the separation unit; a water discharge unit discharging the water separated by the separation unit; and a precipitation unit precipitating and discharging the impurities separated by the separation unit.

Description

Oil-water separation device for oil sand plant {APPARATUS FOR SEPARATING OIL-WATER FROM OIL SAND PLANT}

The present invention relates to an oil-water separation device of an oil sand plant, and more specifically, a multi-stage while floating a small amount of oil contained in the separated water discharged after being separated from the bitumen in the bitumen separation device of the oil sand plant. A small amount of oil, water, and impurities are separated by a circular separator plate, and the separated traces of oil are discharged from the upper part as they float upward and recovered, and the oil and layer-separated water are discharged separately for reuse. Relates to an oil-water separation device for an oil sand plant that can be removed by sedimentation.

Oil sands contain bitumen, sand, water, clay and trace minerals, among which bitumen is a key component that makes oil sands meaningful as an oil resource.

As a commonly known bitumen extraction method, oil sands are extracted and then bitumen is extracted (after mining) and in-situ is extracted directly from bitumen.

By injecting high pressure, high temperature (about 350 ℃) steam where the oil sand is buried, the oil sand mass is fragmented by steam pressure, and the bitumen is melted by the high temperature of the steam, and then the heated bitumen is pumped to the ground. CSS (cyclic steam stimulation) method of raising, after excavating two parallel and horizontal wells, injecting steam into the upper well to generate hot heat to lower the viscosity of the crude oil, and if the lowered viscosity of the crude oil accumulates in the well located at the bottom The SAGD (steam assisted gravity drainage) method of raising to the ground is applied to the in-situ extraction method.

The extract extracted by the SAGD method is separated into liquid and solid in the bitumen separator, and the separated liquid is separated into water and bitumen again, and water is discharged to the outside through the lower pipe of the bitumen separator. do.

A trace amount of oil component and solid impurities that are not separated from the bitumen separator remain in the separation water.

On the other hand, in order to reuse the water contained in the separated water, it is necessary to remove trace oil components and solid impurities, and for this purpose, floating oil separation method, micro bubble bubble type oil separation method, laser oil separation method, specific gravity Various oil-water separation techniques, such as a method of separating oil and water to settle on heavy oil, have been disclosed.

However, the conventional oil-water separation technology as described above is a device having good advantages and separation efficiency, but some technologies have good separation efficiency, but the separation time is increased and the separation facility is large, and some facilities are united with oil components. Separation performance is improved by increasing the particle size, but there are disadvantages of increased power cost and complicated maintenance.

Therefore, it is necessary to develop an oil-water separation device that can be installed on the oil sand plant site and is composed of a single device and has excellent separation efficiency.

Japanese Registered Patent No. 6028811 (Registration Date 2016. 10. 14)

The object of the present invention for solving the problems according to the prior art is to multiply round the separation while floating a small amount of oil contained in the separated water discharged after being separated from the bitumen in the bitumen separation device of the oil sand plant A small amount of oil, water, and impurities are separated by a plate, and recovery is possible as the separated small amount of oil floats upward, and oil and layered water are separately discharged for reuse, and impurities are precipitated and discharged. It is to provide a water separation device of the oil sand plant that can be removed by.

In other words, the running water of an oil sand plant that separates and recovers the separated water mixed with a small amount of oil, water, and impurities by using micro bubbles to separate and recover by type using separation methods such as accompanying rise, collision sedimentation, and overflow of fine oil. It is intended to provide a separation device.

The oil-water separation device of the oil sand plant of the present invention for solving the above technical problem is an inlet that forms a mixed water in which microbubbles are mixed in the separated water by mixing the separated water generated in the process of processing the oil sand with air. ; A separating part that allows water, oil, and impurities contained in the separating water to be separated into respective components while the mixed water introduced through the inlet part flows in and rises; An oil recovery unit for recovering oil separated by the separation unit; A water discharge unit for discharging water separated by the separation unit; And a sedimentation unit for separating and separating impurities separated by the separation unit.

Preferably, the inlet portion, a first suction port for suctioning the separation water; A second suction port for sucking the air; A rotary blade mixing mixed water sucked through the first suction port and air sucked through the second suction port to form a mixed water in which microbubbles are mixed in the separated water; And a discharge port for introducing the mixed water into the separation unit.

Preferably, the separation unit, a cylindrical separation processor through which the mixed water is introduced into the lower side through the inlet; And a circular separating plate formed in a shape of an upper and lower strait with an open top, and a pipe connected downward from the central bottom surface integrally.

Preferably, the circular separating plate is formed integrally with a separating plate wing that is inclined toward the upper side from the upper end portion, a predetermined gap is formed between the end of the separating plate wing and the inner surface of the separating processor, and the mixing The number can be configured to flow through the predetermined gap.

Preferably, the plurality of circular separators are configured and arranged vertically and vertically, and the lower end of the pipe of the upper circular separator is configured to be spaced apart from the central bottom of the lower circular separator by a predetermined gap. Impurities contained in the mixed water may fall and flow into the sedimentation part.

Preferably, the oil recovery part is located on the upper portion of the circular separation plate, the upper and lower portions are formed in an open cylindrical shape, and the lower outer periphery is provided with a shielding portion formed to be shielded between the inner surface of the separation processor. , On the upper end, a plurality of protruding parts and discharge parts are formed at equal intervals, and monthly wear to flow oil contained in the mixed water through the discharge parts; An oil discharge pipe communicating with a lower portion of the shield to discharge the oil flowed through the overflow wear and extending to the outside of the separation processor; And a gas discharge pipe formed in communication with the upper portion of the separation processor.

Preferably, the water discharge portion, the water discharge pipe connected to a position higher than the circular separation plate, lower than the overflow wear; A water level control valve provided in the water discharge pipe; And it can be configured to include; a water level meter for detecting the water level in the separation processor.

Preferably, the sedimentation unit comprises: a sedimentation hopper integrally formed in the shape of a hopper under the separation processor; A sedimentation chute provided to penetrate the center of the bottom surface of the separation processor and introducing impurities discharged through the pipe of the circular separating plate into the sedimentation hopper; And a sediment discharge pipe discharging impurities collected in the sedimentation hopper.

The present invention as described above, as well as to remove the trace oil and impurities contained in the separating water generated after the sand, bitumen is removed from the oil sand plant can be recycled as water, as well as being separated and recovered in separated water There is an advantage to increase the oil production by including the oil in the bitumen.

In addition, since all separation facilities are installed in a single separation tank, it is easy to transport and easy to install on the site, which is effective in using economical and stable facilities.

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 following description.

1 is a schematic configuration diagram showing an oil-water separation device of an oil sand plant according to an embodiment of the present invention.
Figure 2 is a perspective view showing a circular separation plate constituting the bitumen separation device of the oil sand according to an embodiment of the present invention.
Figure 3 is a perspective view showing the overflow wear constituting the bitumen separating device of the oil sand according to an embodiment of the present invention.

The present invention can be implemented in various other forms without departing from its technical spirit or main characteristics. Accordingly, the embodiments of the present invention are merely illustrative in all respects and should not be construed as limiting.

Terms such as first and second may be used to describe various components, but the components should not be limited by the terms.

The terms are used only for the purpose of distinguishing one component from other components. For example, the first component may be referred to as a second component without departing from the scope of the present invention, and similarly, the second component may be referred to as a first component.

The term and / or includes a combination of plural items or any one of plural items.

When an element is said to be 'connected' or 'connected' to another component, it is understood that other components may be directly connected or connected to the other component, but may exist in the middle. It should be.

On the other hand, when a component is said to be 'directly connected' or 'directly connected' to another component, it should be understood that no other component exists in the middle.

The terms used in this application are only used to describe specific embodiments, and are not intended to limit the present invention. Singular expressions include plural expressions unless the context clearly indicates otherwise.

In this application, the terms 'include', 'have', 'have', etc. are intended to designate the existence of features, numbers, steps, operations, components, parts or combinations thereof described in the specification. Or further features or numbers, steps, operations, components, parts, or combinations thereof, should not be excluded in advance.

Unless defined otherwise, all terms used herein, including technical or scientific terms, have the same meaning as commonly understood by a person skilled in the art to which the present invention pertains.

Terms such as those defined in a commonly used dictionary should be interpreted as having meanings consistent with meanings in the context of related technologies, and should not be interpreted as ideal or excessively formal meanings unless explicitly defined in the present application. Does not.

Hereinafter, preferred embodiments according to the present invention will be described in detail with reference to the accompanying drawings, but the same or corresponding elements are assigned the same reference numbers regardless of the reference numerals, and overlapping descriptions thereof will be omitted.

In the description of the present invention, when it is determined that a detailed description of known technologies related to the present invention may obscure the subject matter of the present invention, the detailed description will be omitted.

1 is a schematic configuration diagram showing an oil-water separation device of an oil sand plant according to an embodiment of the present invention, and FIG. 2 is a circular separation plate constituting a bitumen separation device of an oil sand according to an embodiment of the present invention 3 is a perspective view showing the overflow wear constituting the bitumen separating device of the oil sand according to an embodiment of the present invention.

Oil-water separation device of an oil sand plant according to an embodiment of the present invention, as shown in Figure 1, is configured to include an inlet, a separator, an oil recovery unit, a water discharge unit and sedimentation unit.

The inlet part is a part forming a mixed water in which microbubbles are mixed in the separated water as the separated water generated in the process of treating the oil sand is mixed with air.

The separation part is a part that allows water, oil, and impurities contained in the separation water to be separated into respective components as the mixed water introduced through the introduction part flows in and rises.

The oil recovery part is a part for recovering oil separated by the separation part.

The water discharge portion is a portion for discharging water separated by the separation portion.

The sedimentation part is a part in which impurities separated by the separating part are precipitated and discharged.

First, the inlet is described.

The inlet, as shown in Figure 1, the first suction port for sucking the separation water, the second suction port for sucking the air, the separation water sucked through the first suction port and the second suction port It comprises a rotary blade to form the mixed water mixed with the microbubbles in the separated water by mixing the sucked air and a discharge port for introducing the mixed water into the separation unit, for example, may be configured as a turbine pump.

Specifically, the turbine pump constituting the inlet is a pump capable of transporting the mixed liquid by mixing two substances in the pump itself, separated water is introduced through the first suction port of the two ports provided in the turbine pump , The air is introduced through the second inlet port, and the separated water and air introduced into the pump are mixed by the rotary blade provided inside the pump so that finely crushed micro bubbles can be mixed in the separated water.

As described above, the mixed water formed by mixing fine bubbles crushed in the separated water is supplied to the separation unit.

Next, the separation unit will be described.

As shown in FIG. 1, the separation unit is formed in a shape of a cylindrical separation processor in which mixed water flows through the inlet to one side of the lower portion, and an upper gangneopsis (Up 廣 下 狹) in which the upper portion is opened and downward from the central bottom. The connected pipe is configured to include a circular separator formed integrally, and the circular separator may be configured to be stacked in multiple stages.

The separation processor is formed in a cylindrical shape as a whole, and provides a space for separating oil, water, and impurities in the mixed water by receiving the mixed water introduced through the inlet.

The upper and lower parts of the inlet tube are formed in a closed shape as a whole, and the lower part of the inlet tube is blocked by a plate to be partitioned with a sedimentation hopper, and a hole through which the sedimentation chute penetrates the plate forming the lower part of the inlet tube. This is formed, and a gas discharge pipe is formed on the upper portion of the inlet tube.

The plate partitioning the lower portion of the inlet tube and the sedimentation hopper prevents the mixed water supplied from the inlet portion from directly flowing into the sedimentation hopper, so that the mixed water supplied from the inlet portion rises upward.

1 and 2, as shown in FIGS. 1 and 2, a separator blade formed inclined toward an upper side from the upper end is integrally formed, and between an end of the separator blade and an inner surface of the inflow cylinder A predetermined gap G is formed, and the mixed water may be configured to flow through the predetermined gap G.

Specifically, the circular separating plate is formed in a semi-circular shape in the shape of an upper and lower nymph (or glass glass) as a whole, and the wings of the separating plate shortly formed upward toward the outside from the upper end are integrally formed and penetrated downward from the central bottom surface. The connected pipe is formed in a long form.

When the circular separation plate is installed in the inner space of the inflow container, a predetermined gap G is formed using a separate bracket or the like, wherein the predetermined gap G is formed at intervals of 2 cm to 3 cm. desirable.

As described above, the circular separator is composed of a plurality and is installed in a stacked structure arranged vertically at regular intervals. Specifically, the lower end of the pipe of the upper circular separator is at the central bottom of the lower circular separator. It is configured to be spaced apart from a predetermined gap, and impurities contained in the mixed water may fall through the pipe to flow into the sediment.

On the other hand, as the lower end of the pipe of the upper circular separation plate is disposed at a predetermined gap from the central bottom of the lower circular separation plate, impurities can be introduced into the sedimentation portion through this gap.

On the other hand, the mixed water introduced into the separation processor may be separated into oil, water, and impurities by the circular separator, respectively, the three circular separators of FIG. 1, the lower circular separator, the central circular separator, The separation process is described by dividing it into an upper circular separator.

When the mixed water (oil, water, impurity and microbubbles mixed) supplied by the inflow part rises as it flows into the separation processor, it rises in the semicircular direction on the semicircular surface of the bottom of the main body of the circular separation plate and then rises to the separation processor As it passes through the narrow air gap (G) between the inner side of the inner plate and the blades of the circular plate, it descends to the upper surface of the circular plate in a state where the ascent rate is fast and spreads from narrow to wide by Bernoulli's definition. As the descending speed decreases, a diffraction phenomenon in which the rising direction and the descending direction are rapidly changed from the wings of the edge of the circular separator occurs, and light substances float upward due to gravity, and the heavier the material, the easier it is pushed down to the center of the upper surface of the circular separator to diffract water and impurities After filling the semi-circular center of the top of the semi-circular body of this circular separator, the descent stops and rises again The heavy impurities are settled by the sediment discharge pipe provided at the lower center of the circular separator, and through this process, a plurality of circular separators, which are vertically constructed 3, pass through the same principle, so that the oil, water and impurities contained in the mixed water are Each is separated.

On the other hand, as described above, the efficiency of separating oil, water, and impurities contained in the mixed water by the circular separator is gradually increased as it passes through a plurality of circular separators step by step.

As described above, the oil, water, and impurities contained in the separation water are separated by the separation processor and the circular separation plate constituting the separation unit, and the separated oil is collected at the top of the separation processor, and the separated water is separated. It is collected at the bottom of the processor, and the separated impurities are collected at a sedimentation hopper.

Next, the oil recovery unit will be described.

The oil recovery unit, as shown in Figures 1 and 3, is located on the upper portion of the circular separation plate, the upper and lower portions are formed in an open cylindrical shape, and the lower outer circumference is between the inner surface of the separation processor. A shielding portion formed to be shielded is provided, and a plurality of protrusions and discharge portions are formed at equal intervals at the top, and a overflowing wearer that flows the oil contained in the mixed water through the discharger, discharges the oil flowed through the wearer. It can be configured to include a gas discharge pipe formed in communication with the upper portion of the separation processor and the oil discharge pipe extending to the outside of the separation processor to communicate with the lower portion of the shield.

The oil recovery part collects and collects oil that is separated from the water component of the separation water by a microbubble and floats on the inside of the separation processor through the discharge part of the monthly wear, and collects and collects the oil. It is desirable to attach it at a higher position than the highest installed circular separator.

The oil discharge pipe should be installed in a form connected to the lower portion of the shield forming the overflow wear, and thus the oil collected through the overflow wear is always installed as it is configured in the form of a pipe extending from the lower part of the shield to the outside of the separation processor. It can flow out of the separation processor.

The gas discharge pipe should be installed on the upper part of the separation processor so that the microbubbles are discharged to the atmosphere.

As described above, the trace amount of oil contained in the mixed water can be separated and collected and recovered by the oil recovery unit.

Next, the water discharge portion will be described.

As shown in FIG. 1, the water discharge part is higher than a circular separation plate installed at the highest among a plurality of circular separation plates, and is connected to a lower position than the monthly wear, and connected to the outside, a water discharge pipe, and a water level provided in the water discharge pipe. It may be configured to include a control valve and a water level gauge for detecting the water level in the separation processor.

Normally, when operating the oil-water separation device, if the oil content in the mixed water (oil, water, impurities and fine bubbles mixed) is high, the water level controller is adjusted to open the water level control valve at a low level to separate the water from the mixed water. It is operated so that water is discharged, and if the oil content in the mixed water is low, the operation by increasing the water level will be an operation method to increase the separation efficiency of oil.

As described above, water contained in the mixed water may be separated and discharged by the water discharge unit to become a reusable state.

Next, the settling portion will be described.

As shown in FIG. 1, the sedimentation part is provided with a sedimentation hopper integrally formed in the shape of a hopper at the bottom of the separating processor, and is provided to penetrate the center of the bottom surface of the separating processor to remove impurities discharged through the pipe of the circular separating plate. It may be configured to include a sedimentation chute that flows into the sedimentation hopper and a sediment discharge pipe to discharge impurities collected in the sedimentation hopper.

As described above, impurities contained in the mixed water may be separated and discharged by the sedimentation unit.

Although the present invention has been described with reference to the accompanying drawings and preferred embodiments, it is apparent to those skilled in the art that many various and obvious modifications are possible without departing from the scope of the present invention. Therefore, the scope of the present invention should be interpreted by the claims described to include many of these modifications.

100: inlet 110: first suction port
120: second suction port 130: rotary wing
140: discharge port 200: separation unit
210: separation processor 220: circular separation plate
221: Pipe 222: Separator wing
300: oil recovery unit 310: monthly wear
311: shield 312: protrusion
313: discharge unit 320: oil discharge pipe
330: gas discharge pipe 400: water discharge section
410: water discharge pipe 420: water level control valve
430: water level meter 500: sediment
510: sedimentation hopper 520: sedimentation suit
530: Sediment discharge pipe G: Clearance

Claims (8)

An inlet for forming mixed water in which microbubbles are mixed in the separated water by mixing the separated water generated in the process of processing the oil sand with air; A separating part that allows water, oil, and impurities contained in the separating water to be separated into respective components while the mixed water introduced through the inlet part flows in and rises; An oil recovery unit for recovering oil separated by the separation unit; A water discharge unit for discharging water separated by the separation unit; And a sedimentation unit for separating and separating impurities separated by the separation unit.
The separation unit,
A cylindrical separation processor through which the mixed water flows to the lower side through the inlet; And a circular separating plate formed in the shape of an upper and lower strait with the upper portion open and a pipe connected downward from the central bottom surface integrally formed.
The circular separator,
Separator blades formed obliquely toward the upper side from the upper end are integrally formed, and a predetermined gap is formed between the end of the separator plate and the inner surface of the separation processor, and the mixed water flows through the predetermined gap. Oil sand separation device of the oil sand plant, characterized in that configured. According to claim 1,
The inlet,
A first suction port for suctioning the separated water;
A second suction port for sucking the air;
A rotary blade mixing mixed water sucked through the first suction port and air sucked through the second suction port to form a mixed water in which microbubbles are mixed in the separated water; And
A discharge port for introducing the mixed water into the separator; an oil-water separation device for an oil sand plant, characterized in that it comprises a turbine pump. delete delete According to claim 1,
The circular separator is composed of a plurality and arranged vertically and vertically, and the lower end of the pipe of the upper circular separator is configured to be spaced apart at a predetermined gap from the central bottom of the lower circular separator, and through the pipe, the mixed water Oil sand separation device of the oil sand plant, characterized in that the impurities contained therein are dropped and flow into the sediment. According to claim 1,
The oil recovery unit,
Located on the upper portion of the circular separation plate, the upper and lower portions are formed in an open cylindrical shape, and the lower outer periphery is provided with a shield formed extending to be shielded between the inner surface of the separation processor, and at the upper end, a plurality of protrusions and discharges Overflow wear that is formed at equal intervals and overflows the oil contained in the mixed water through the discharge portion;
An oil discharge pipe communicating with a lower portion of the shield to discharge the oil flowed through the overflow wear and extending to the outside of the separation processor; And
Oil separation plant of the oil sand plant, characterized in that comprises a; gas discharge pipe formed in communication with the upper portion of the separation processor. The method of claim 6,
The water outlet,
A water discharge pipe connected to a position higher than the circular separation plate and lower than the overflow wear;
A water level control valve provided in the water discharge pipe; And
Water level separation device of the oil sand plant, characterized in that comprises a; water level meter for detecting the water level in the separation processor. According to claim 1,
The sedimentation part,
A sedimentation hopper integrally formed in the shape of a hopper at the bottom of the separation processor;
A sedimentation chute provided to penetrate the center of the bottom surface of the separation processor and introducing impurities discharged through the pipe of the circular separating plate into the sedimentation hopper; And
Oil separating device of the oil sand plant, characterized in that comprises a; sediment discharge pipe for discharging the impurities collected in the sedimentation hopper.

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