KR102239829B1 - Apparatus and method for testing degasser - Google Patents

Abstract

The present invention relates to an apparatus and method for testing a gas-liquid separator that separates a mixture of mud and gas into mud and gas. According to an embodiment of the present invention, there is provided an apparatus for testing a gas-liquid separator, comprising: a first mud tank for storing mud before flowing into the gas-liquid separator; A perforated pipe having a plurality of holes on its surface, the gas injection pipe for injecting gas into the mud stored in the first mud tank through the plurality of holes; And a second mud tank for storing mud discharged from the gas-liquid separator, wherein mud stored in the first mud tank is sucked into the gas-liquid separator, after gas is removed from the gas-liquid separator, and the second mud tank A gas-liquid separator testing apparatus is provided in which the performance of the gas-liquid separator is evaluated by using the gas content of the mud stored in the first mud tank and the gas content of the mud stored in the second mud tank.

Description

Gas-liquid separator test apparatus and method {APPARATUS AND METHOD FOR TESTING DEGASSER}

The present invention relates to a gas-liquid separator, and more particularly, to an apparatus and method for testing a gas-liquid separator for separating a mixture of mud and gas into mud and gas.

As the international rapid industrialization and industry develop, the use of resources such as petroleum is gradually increasing, and accordingly, stable production and supply of oil is emerging as a very important issue at a global level.

For this reason, in recent years, the development of marginal fields or deep-sea oil fields, which have been neglected due to lack of economics, has become economical. Accordingly, with the development of subsea mining technology, a drilling vessel equipped with a drilling facility suitable for the development of such oil fields has been developed.

In the conventional seabed drilling, a fixed platform for drilling work by anchoring at a point in the offshore was mainly used, but recently floating drilling facilities capable of drilling work in deep seas of 3,000m or more have been developed and are used for underwater drilling.

These drilling facilities are equipped with various drilling-related equipment such as a derrick system, a riser, and a drill pipe to drill oil or gas existing under the sea floor.

In the center of a rig ship or a drilling ship (hereinafter referred to as a drilling ship) equipped with various drilling equipment so that oil or gas existing under the sea floor can be drilled, a riser for drilling oil or gas existing under the sea floor. ) Or a moonpool is formed so that a drill pipe can be moved up and down.

1 is a side view showing a drilling operation of a conventional drilling vessel.

Referring to FIG. 1, by moving the riser 3 and the drill pipe 4 downward through the moonpool 2 formed in the center of the drilling vessel, the reservoir 11 under the sea bed 5 Drilling the seabed resources stored in the well (12) located in ).

The derrick (1) is a structure equipped with various equipment for drilling, and is also called a drilling tower. Derrick (1) is a lattice tower made of steel and has a complex steel structure.

The riser 3 is a member that advances the drill pipe 4 to the seabed 5 in advance before advancing the drill pipe 4 to the oil well 12 and provides a passage for the mud to return.

When the riser 3 is installed, the drill pipe 4 into the riser 3 advances downward to the oil well 12 through the subsea stratum 10.

In this way, when the riser 3 is advanced downward to the bottom of the sea 5 or the drill pipe 4 is advanced to the oil well 12, it is necessary to advance the elongated riser 3 or the drill pipe 4 downward. Rather, the short-length riser 3 or the drill pipe 4 is connected to each other to advance downward.

An explosion prevention stack (BOP, blowout preventer) 6 is installed on the seabed 5 to block abnormal high pressure from rising through the drill pipe 4.

In the subsea stratum 10, after fixing the casing 7 with cement, a drill pipe 4 equipped with a drill bit 9 is inserted into the casing to drill subsea resources.

Mud (8) is inserted into the drill pipe (4) to prevent the drill bit (9) from overheating due to heat generated when the drill bit (9) drills through the ground and to make drilling easier by lubricating it. do. This mud exits through the drill bit 9 and returns back through the casing 7 and riser 3. The mud pushed up contains soil, rock debris, gas, and the like, and is purified by a mud purification device and inserted into the drill pipe 4 again. At this time, a gas-liquid separator is a device that extracts gas from the pushed-up mode, and a vacuum-type gas-liquid separator is mainly used. The vacuum type gas-liquid separator creates a vacuum at the top to suck gas in the mud and discharge the mud in which the gas was sucked.

If the gas-liquid separator does not work properly during drilling, it will interfere with the drilling operation, so it is necessary that the gas-liquid separator be tested before being used in the actual drilling site. And, when a new gas-liquid separator is developed, it needs to be tested for performance evaluation. However, there is a problem in that there is no apparatus and method for testing a gas-liquid separator in the related art.

Prior art: Domestic Publication No. 10-2012-0132595 (published on Dec. 6, 2012)

It is an object of the present invention to provide an apparatus and method for testing a gas-liquid separator that separates a mixture of mud and gas into mud and gas.

According to an embodiment of the present invention for achieving the above object, there is provided a gas-liquid separator testing apparatus, comprising: a first mud tank for storing mud before flowing into the gas-liquid separator; A perforated pipe having a plurality of holes on its surface, the gas injection pipe for injecting gas into the mud stored in the first mud tank through the plurality of holes; And a second mud tank for storing mud discharged from the gas-liquid separator, wherein mud stored in the first mud tank is sucked into the gas-liquid separator, after gas is removed from the gas-liquid separator, and the second mud tank A gas-liquid separator testing apparatus is provided in which the performance of the gas-liquid separator is evaluated by using the gas content of the mud stored in the first mud tank and the gas content of the mud stored in the second mud tank.

In particular, the gas content of the mud stored in the first mud tank is calculated using the density of the mud to which gas is not injected and the mass per unit volume of the mud stored in the first mud tank, and the mud stored in the second mud tank The gas content of may be calculated using the density of mud to which gas is not injected and the mass per unit volume of mud stored in the second mud tank.

In addition, the mass per unit volume of mud stored in the first mud tank may be measured after centrifuging the mud stored in the first mud tank in a standard cylinder.

In addition, the shape of the gas injection pipe may be determined according to the shape of the first mud tank.

In addition, the shape of the gas injection pipe may be a'C'.

In addition, the gas-liquid separator test apparatus may further include a compressor that compresses gas and supplies it to the gas injection pipe.

In addition, the gas-liquid separator test apparatus may further include a mud suction pipe for sucking mud stored in the first mud tank into the gas-liquid separator.

In addition, the gas-liquid separator test apparatus may further include a discharge device for sucking mud from which gas has been removed from the air and discharging it to the second mud tank.

In addition, the gas-liquid separator may be a vacuum type gas-liquid separator.

According to another embodiment of the present invention for achieving the above object, in a gas-liquid separator test method, the steps of: injecting gas into mud stored in a first mud tank using a gas injection pipe having a plurality of holes on its surface; Sucking the mud stored in the first mud tank into the gas-liquid separator to remove the gas, and discharging the mud from which the gas has been removed to a second mud tank; And evaluating the performance of the gas-liquid separator using the gas content of the mud into which the gas stored in the first mud tank is injected and the gas content of the mud discharged to the second mud tank. Is provided.

In particular, the gas-liquid separator test method further includes measuring the density of the mud to which gas is not injected prior to the injecting step, and the evaluating step may evaluate the performance of the gas-liquid separator using the density. .

In addition, the gas-liquid separator test method includes the steps of: putting the mud into which the gas stored in the first mud tank is injected into a first standard cylinder; Putting the mud discharged into the second mud tank into a second standard cylinder; Measuring a mass of mud contained in the first standard cylinder and a mass of mud contained in the second standard cylinder; Calculating a gas content of the mud into which the gas stored in the first mud tank is injected using the mass and the density of the mud contained in the first standard cylinder; And calculating the gas content of the mud discharged to the second mud tank using the mass and the density of the mud contained in the second standard cylinder.

In addition, the gas-liquid separator test method includes the steps of: putting the mud into which the gas stored in the first mud tank is injected into a first standard cylinder; Putting the mud discharged into the second mud tank into a second standard cylinder; Centrifuging the mud contained in the first standard cylinder and the mud contained in the second standard cylinder; Measuring a volume of mud contained in the first standard cylinder and a volume of mud contained in the second standard cylinder; And evaluating the performance of the gas-liquid separator using the volume of mud contained in the first standard cylinder and the volume of mud contained in the second standard cylinder.

In addition, the gas-liquid separator may be a vacuum type gas-liquid separator.

In addition, the shape of the gas injection pipe may be determined according to the shape of the first mud tank.

In addition, the shape of the gas injection pipe may be a'C'.

According to an embodiment of the present invention, by proposing an apparatus and method for testing a gas-liquid separator, it is possible to test whether the gas-liquid separator is normally operated before the gas-liquid separator is used in a drilling site, and when a new gas-liquid separator is developed, a new gas-liquid separator You can test the performance.

1 is a side view showing a drilling operation of a conventional drilling vessel.
FIG. 2 is a diagram illustrating testing of a gas-liquid separator using a gas-liquid separator testing apparatus according to an exemplary embodiment of the present invention.
3 is a view showing a gas injection pipe of the gas-liquid separator test apparatus according to an embodiment of the present invention.
4 is a view showing a method of measuring the gas discharge capacity of the gas-liquid separator according to an embodiment of the present invention.
5 is a view showing a gas-liquid separator test method according to an embodiment of the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. First of all, in adding reference numerals to elements of each drawing, it should be noted that the same elements are assigned the same numerals as possible even if they are indicated on different drawings. In addition, in describing the present invention, when it is determined that a detailed description of a related known configuration or function may obscure the subject matter of the present invention, a detailed description thereof will be omitted.

First, a gas-liquid separator test apparatus according to an embodiment of the present invention will be described with reference to FIGS. 2 to 4.

FIG. 2 is a view showing a gas-liquid separator testing apparatus using a gas-liquid separator testing apparatus according to an embodiment of the present invention, and FIG. 3 is a view showing a gas injection pipe of a gas-liquid separator testing apparatus according to an embodiment of the present invention, 4 is a view showing a method of measuring the gas discharge capacity of the gas-liquid separator according to an embodiment of the present invention.

2, the gas-liquid separator test apparatus according to the embodiment of the present invention includes a gas injection pipe 210, a first mud tank 220, a compressor 230, and a mud suction. A mud suction pipe 240, an eductor 250, and a second mud tank 260 are included.

The first mud tank 220 is a tank that stores mud before flowing into the gas-liquid separator 270.

The compressor 230 compresses the gas and supplies it to the gas injection pipe 210.

The gas injection pipe 210 is a porous pipe having a plurality of holes on its surface, and injects gas into the mud stored in the first mud tank 220 through the plurality of holes.

As shown in FIG. 3, there are a plurality of small holes in the surface of the gas injection pipe 210. The gas injection pipe 210 injects gas bubbles into the mud through a plurality of holes on the surface. In this case, when the size of the gas bubbles is large, the gas bubbles may be injected into the mud and diffuse into the air at the same time. Therefore, it is preferable that the size of the holes on the surface of the gas injection pipe 210 is small so that the size of the gas bubble can be small. In particular, the size of the holes on the surface of the gas injection pipe 210 is preferably greater than 0 mm and less than or equal to 5 mm.

In addition, the shape of the gas injection pipe 210 may be determined according to the shape of the first mud tank 210. When the shape of the first mud tank 210 is a rectangular parallelepiped, I can.

The mud suction pipe 240 sucks the mud stored in the first mud tank 220 into the gas-liquid separator 270.

The mud sucked into the gas-liquid separator 270 is separated into gas and mud in the gas-liquid separator 270, and the mud from which the gas has been removed is discharged to the second mud tank 260 through the discharge device 250.

2 shows a vacuum type gas-liquid separator 270. The vacuum type gas-liquid separator 270 uses a vacuum pump 271 to lower the pressure inside the gas-liquid separator 270, and as the pressure inside the gas-liquid separator 270 decreases, the mud in the first mud tank is removed from the gas-liquid separator 270. ) It is sucked inside. As the sucked mud flows along the leaf 272, gas flows upward and mud flows downward. In addition, the mud from which the gas has been removed is sucked through the discharge device 250 and discharged to the second mud tank 260.

According to an embodiment of the present invention, the performance of the gas-liquid separator 270 is evaluated using at least one of the gas content of the mud stored in the first mud tank 210 and the gas content of the mud stored in the second mud tank 260 do.

Referring to FIG. 3, a method of evaluating the performance of a gas-liquid separator according to an embodiment of the present invention will be described. First, before gas is injected into the mud stored in the first mud tank 210, the density of the mud to which the gas is not injected is measured. In this case, the density may be calculated by measuring the mass after containing mud in which gas is not injected in a standard cylinder.

Then, gas is injected into the mud stored in the first mud tank 210 using the gas injection pipe 210. Then, the mud stored in the first mud tank 210 is put into a standard cylinder, and then the mud stored in the first mud tank 210 is sucked into the gas-liquid separator 270. Then, when the mud that has passed through the gas-liquid separator 270 is discharged to the second mud tank 260, the mud of the second mud tank 260 is put in a standard cylinder.

First, looking at the first measurement method, as shown in FIG. 4, the mass of the standard cylinder containing the mud of the first mud tank 210 and the standard cylinder containing the mud of the second mud tank 260 is measured. 1 The mass per unit volume of mud in the mud tank 210 and the mass per unit volume of mud in the second mud tank 270 are calculated.

In addition, the gas content of the mud stored in the first mud tank 210 is calculated using the density of the mud to which the gas is not injected and the mass per unit volume of the mud in the first mud tank 210. That is, the mass per unit volume of mud without gas is calculated by using the density of mud to which gas is not injected, and the mass per unit volume of mud without gas and the unit of mud of the first mud tank 210 Find the difference in mass per volume. And, if the volume of mud to which gas is not injected as much as the difference is calculated using the density of mud to which gas is not injected, the volume of gas contained in the mud of the unit volume stored in the first mud tank 210 can be calculated. I can. In addition, the gas content of the mud stored in the first mud tank 210 may be obtained by using the volume of gas contained in the mud of the unit volume stored in the first mud tank 210.

Then, in the same manner as above, the gas content of the mud stored in the second mud tank 270 is calculated.

Then, the discharge capacity of the gas-liquid separator 260 is evaluated using the gas content of the mud stored in the first mud tank 210 and the gas content of the mud stored in the second mud tank 270. For example, if the gas content of the mud stored in the first mud tank 210 is 30% and the gas content of the mud stored in the second mud tank 270 is 5%, the discharge capacity of the gas-liquid separator 270 is 83.33 We believe it is (25/30)%.

Next, looking at the secondary measurement method, as shown in FIG. 4, the mud of the first mud tank 210 contained in the standard cylinder and the mud of the second mud tank 270 contained in the standard cylinder are centrifuged. Centrifuge using a separator. The gas is then released into the atmosphere, leaving only pure mud. Looking closer, grains such as soil and sand settle at the bottom, and liquids such as water are above them, and gases are released into the atmosphere. At this time, grains such as soil and sand and liquid are combined and referred to as mud.

After centrifugation, the gas content of the mud stored in the first mud tank 210 can be obtained by measuring the volume of the mud in the standard cylinder containing the mud in the first mud tank 210. The gas content of the mud stored in the second mud tank 210 may be obtained by measuring the volume of the mud in the standard cylinder containing the mud. And, it is possible to determine the discharge capacity of the gas-liquid separator 270 using this.

In addition, the mass of the standard cylinder containing mud of the first mud tank 210 and the standard cylinder containing the mud of the second mud tank 260 may be measured to measure the mass of mud contained in each of the standard cylinders. A more accurate result can be obtained by measuring the mass after completely removing the gas contained in the mud by using centrifugal separation.

The discharge capacity of the gas-liquid separator may be measured using both the primary and secondary measurement methods, or the discharge capacity of the gas-liquid separator may be measured using one of the first and second measurement methods. .

Next, a gas-liquid separator test method according to an embodiment of the present invention will be described with reference to FIG. 5. 5 is a view showing a gas-liquid separator test method according to an embodiment of the present invention.

As shown in FIG. 5, the density of mud to which gas is not injected is measured (S510). At this time, before injecting gas into the mud stored in the first mud tank 210, the mud stored in the first mud tank 210 is put in a standard cylinder, and then the mass is measured to calculate the density.

Then, gas is injected into the mud stored in the first mud tank 210 (S520), and the mud into which the gas stored in the first mud tank 210 is injected is put into a first standard cylinder (S530). When the mud stored in the first mud tank 210 is sucked into the gas-liquid separator 270 (S540), after the gas is removed from the mud in the gas-liquid separator 270, the mud from which the gas has been removed is the second mud tank 260. It is discharged to (S550), and put the mud of the second mud tank 260 in the second standard cylinder (S560).

The mass of the mud contained in the first standard cylinder and the mass of the mud contained in the second standard cylinder are measured (S571), and the density of the mud without gas injection, the mass of the mud contained in the first standard cylinder, and the second standard cylinder The performance of the gas-liquid separator 270 is evaluated using the mass of mud contained in (S572).

Then, the mud of the first standard cylinder and the mud of the second standard cylinder are centrifuged (S581), and the volume of mud contained in the first standard cylinder and the volume of mud contained in the second standard cylinder are measured (S582).

Then, the performance of the gas-liquid separator 270 is evaluated using the volume of mud contained in the first standard cylinder and the volume of mud contained in the second standard cylinder (S590).

The above description is merely illustrative of the technical idea of the present invention, and those of ordinary skill in the art to which the present invention pertains will be able to make various modifications and variations without departing from the essential characteristics of the present invention. Accordingly, the embodiments disclosed in the present invention are not intended to limit the technical idea of the present invention, but to explain the technical idea, and the scope of the technical idea of the present invention is not limited by these embodiments. The scope of protection of the present invention should be construed by the following claims, and all technical ideas within the scope equivalent thereto should be construed as being included in the scope of the present invention.

210: gas injection pipe
220: first mud tank
230: compressor
240: mud suction pipe
250: discharge device
260: second mud tank
270: gas-liquid separator

Claims (16)

A gas-liquid separator testing apparatus for testing a gas-liquid separator for separating a mixture of mud and gas into mud and gas before using in a field, comprising: a first mud tank for storing mud before flowing into the gas-liquid separator;
A perforated pipe having a plurality of holes on its surface, the gas injection pipe for injecting gas into the mud stored in the first mud tank through the plurality of holes; And
And a second mud tank for storing mud discharged from the gas-liquid separator,
The mud stored in the first mud tank is sucked into the gas-liquid separator, the gas is removed from the gas-liquid separator, and then discharged to the second mud tank,
A gas-liquid separator testing apparatus in which performance of the gas-liquid separator is evaluated using a gas content of mud stored in the first mud tank and a gas content of mud stored in the second mud tank. The method according to claim 1,
The gas content of the mud stored in the first mud tank is calculated using the density of the mud to which gas is not injected and the mass per unit volume of the mud stored in the first mud tank,
The gas content of the mud stored in the second mud tank is calculated using the density of the mud to which the gas is not injected and the mass per unit volume of the mud stored in the second mud tank. The method according to claim 2,
The mass per unit volume of mud stored in the first mud tank is measured after centrifuging the mud stored in the first mud tank in a standard cylinder. The method according to claim 1,
The shape of the gas injection pipe is determined according to the shape of the first mud tank, gas-liquid separator test apparatus. The method according to claim 1,
The gas injection pipe has a shape of'C', a gas-liquid separator test apparatus. The method according to claim 1,
Gas-liquid separator testing apparatus further comprising a compressor for compressing gas and supplying it to the gas injection pipe. The method according to claim 1,
Gas-liquid separator testing apparatus further comprising a mud suction pipe for sucking the mud stored in the first mud tank to the gas-liquid separator. The method according to claim 1,
Gas-liquid separator testing apparatus further comprising a discharge device for sucking the mud from which the gas has been removed from the gas-liquid separator and discharging the mud to the second mud tank. The method according to claim 1,
The gas-liquid separator is a vacuum type gas-liquid separator, a gas-liquid separator test apparatus. In the gas-liquid separator test method for testing a gas-liquid separator for separating a mixture of mud and gas into mud and gas before using in the field,
Injecting gas into the mud stored in the first mud tank using a gas injection pipe having a plurality of holes on its surface;
Sucking the mud stored in the first mud tank into the gas-liquid separator to remove the gas, and discharging the mud from which the gas has been removed to a second mud tank; And
And evaluating the performance of the gas-liquid separator using the gas content of the mud into which the gas stored in the first mud tank is injected and the gas content of the mud discharged to the second mud tank. The method of claim 10,
Further comprising the step of measuring the density of the mud to which the gas is not injected before the step of injecting,
The evaluating step is to evaluate the performance of the gas-liquid separator using the density, gas-liquid separator test method. The method of claim 11,
Putting the mud into which the gas stored in the first mud tank is injected into a first standard cylinder;
Putting the mud discharged into the second mud tank into a second standard cylinder;
Measuring a mass of mud contained in the first standard cylinder and a mass of mud contained in the second standard cylinder;
Calculating a gas content of the mud into which the gas stored in the first mud tank is injected using the mass and the density of the mud contained in the first standard cylinder; And
The gas-liquid separator test method further comprising the step of calculating the gas content of the mud discharged to the second mud tank using the mass and the density of the mud contained in the second standard cylinder. The method of claim 10,
Putting the mud into which the gas stored in the first mud tank is injected into a first standard cylinder;
Putting the mud discharged into the second mud tank into a second standard cylinder;
Centrifuging the mud contained in the first standard cylinder and the mud contained in the second standard cylinder;
Measuring a volume of mud contained in the first standard cylinder and a volume of mud contained in the second standard cylinder; And
The gas-liquid separator testing method further comprising evaluating the performance of the gas-liquid separator using the volume of mud contained in the first standard cylinder and the volume of mud contained in the second standard cylinder. The method of claim 10,
The gas-liquid separator is a vacuum type gas-liquid separator, gas-liquid separator test method. The method of claim 10,
The shape of the gas injection pipe is determined according to the shape of the first mud tank, gas-liquid separator test method. The method of claim 10,
The shape of the gas injection pipe is'C', the gas-liquid separator test method.

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