CN112576233B

CN112576233B - Gas-liquid-solid separation device in shaft and manufacturing method thereof

Info

Publication number: CN112576233B
Application number: CN202011462246.2A
Authority: CN
Inventors: 梅瀚文
Original assignee: Individual
Current assignee: Individual
Priority date: 2020-12-08
Filing date: 2020-12-08
Publication date: 2022-07-26
Anticipated expiration: 2040-12-08
Also published as: CN112576233A

Abstract

The invention provides a gas-liquid-solid separation device in a shaft, wherein the upper end of an outer pipe is connected to an upper joint through being assembled with an outer buckle, and the upper end of the outer pipe is provided with a plurality of liquid inlet holes penetrating through the upper end of the outer pipe; the inner pipes are inserted into the outer pipes and are spaced from each other, and the upper ends of the inner pipes are assembled and connected with the upper joint through the inner buckles; the diameter-expanding short section is connected to the lower end of the inner pipe to be suspended in the outer pipe; the inner pipe, the expanding short section and the outer pipe together enclose an inner pipe annulus and an outer pipe annulus, and the inner pipe annulus and the outer pipe annulus meet the preset flow area; the flow area of the diameter-expanding short section is not less than that of an externally connected upper pump oil pipe; the lower joint is connected to the lower end of the outer pipe through a screw thread; the lower end of the lifting short section is inserted and connected to the upper end of the upper joint, and the oil pipe joint hoop is connected to the upper end of the lifting short section. The invention also provides a design method of the gas-liquid-solid separation device in the shaft. Compared with the related art, the gas-liquid-solid separation device in the shaft has good reliability and long service life.

Description

Gas-liquid-solid separation device in shaft and manufacturing method thereof

Technical Field

The invention relates to the technical field of coal bed gas well extraction equipment, in particular to a gas-liquid-solid separation device in a shaft and a manufacturing method thereof.

Background

In order to ensure the normal operation of the coal bed gas well extraction equipment, avoid gas lock of gas inlet pump and sand blocking, various gas anchors and sand anchors are adopted. However, the problems of free gas entering the pump, pump gas lock and oil pipe cavitation at different degrees are still not completely avoided; solid particles enter the pump, so that the pump is blocked and still a main factor of pump detection is caused, and the reliability is poor. The gas anchor adopted by the oil well of general mechanical oil extraction is only suitable for the condition of low gas-liquid ratio, while most of coal-bed gas wells have gas-liquid ratio of hundreds or even thousands, and the general gas anchor is difficult to adapt. The oil well can carry the particles with certain particle sizes to a wellhead because the viscosity of crude oil is far greater than that of water, and the water produced by the coal bed gas is not beneficial to carrying the particles, so that the sand anchor which can be used in the oil well has poor effect in the coal bed gas well.

Therefore, there is a need to provide a new gas-liquid-solid separation device in a shaft and a method for manufacturing the same to solve the above problems.

Disclosure of Invention

The invention aims to provide a gas-liquid-solid separation device in a shaft, which has good reliability and long service life, and a manufacturing method thereof.

In order to solve the technical problem, the invention provides a gas-liquid-solid separation device in a shaft, which is applied between a discharge and production pump and a sand-settling pipe of a coal-bed gas well discharge and production device, wherein the gas-liquid-solid separation device in the shaft comprises an oil pipe joint hoop, a lifting short joint, an upper joint, an outer pipe, a liquid inlet hole, an inner pipe, an expanding short joint and a lower joint;

the upper joint is in a hollow ring shape, and the lower end of the upper joint is provided with an outer buckle positioned on the outer side of the upper joint and an inner buckle positioned on the inner side of the upper joint;

the upper end of the outer pipe is assembled and connected with the upper joint through the outer buckle, and the upper end of the outer pipe is provided with a plurality of liquid inlet holes penetrating through the upper end of the outer pipe;

the inner pipe is inserted and accommodated in the outer pipe and spaced from the outer pipe, the upper end of the inner pipe is assembled and connected with the upper joint through the inner buckle, and the inner pipe is communicated with the upper joint;

the diameter-expanding short section is connected to the lower end of the inner pipe to be suspended in the outer pipe, and the diameter-expanding short section and the outer pipe are spaced from each other;

the inner pipe, the diameter-expanding short section and the outer pipe together enclose an inner pipe annulus and an outer pipe annulus, and the inner pipe annulus and the outer pipe annulus meet a preset flow area so as to realize gas-liquid separation;

the overflow area of the diameter-expanding short section is not less than that of the external upper pump oil pipe, so that the flow velocity of liquid at the position of the diameter-expanding short section is lower than that of liquid at any position of the external upper pump oil pipe, and solid particles are settled and separated from the liquid;

the lower joint is connected to the lower end of the outer pipe through a screw thread;

the lower end of the lifting short section is inserted and connected to the upper end of the upper joint, and the oil pipe joint hoop is connected to the upper end of the lifting short section.

Preferably, the liquid inlet holes are distributed downwards from the position of the outer pipe, which is 150mm away from the upper joint, and the aperture and the number of the liquid inlet holes are designed to meet the requirement that the maximum overflowing speed of all the liquid inlet holes is lower than 0.2 m/s.

Preferably, the inner and outer tube annuluses satisfy the predetermined flow area, specifically include:

calculating by using the maximum theoretical displacement of a drainage pump externally connected with the gas-liquid-solid separation device in the shaft, so that the inner diameter of the inner pipe meets the flow velocity of 2 m/s;

the outer diameter of the outer pipe is at least 6mm smaller than the inner diameter of a shaft casing externally connected with the gas-liquid-solid separation device in the shaft;

the inner pipe annulus and the outer pipe annulus meet the floating speed of bubbles with the maximum liquid flow rate lower than 0.1mm in diameter;

the difference between the inner diameter of the outer pipe and the outer diameter of the diameter-expanding short section is larger than 10 mm;

the length of the outer pipe satisfies that the effective separation volume of the inner pipe annulus and the outer pipe annulus is larger than the single suction volume of the drainage pump.

Preferably, the clearance distance between the lower end of the diameter-expanding short joint and the lower joint is at least 200 mm.

Preferably, the upper end of the upper joint is connected with the lifting sub and the tubing coupling, and the upper joint comprises:

the length of the lifting short section is 400mm, the diameter of the lifting short section is consistent with that of an externally connected upper pumping oil pipe, and the diameter of the oil pipe joint hoop is matched with that of the lifting short section.

The present invention also provides a method for manufacturing the gas-liquid-solid separation device in the shaft, which comprises the following steps:

step S1, designing specification parameters of the outer pipe and the inner pipe:

based on the floating speed of the bubbles of the leaf being 0.2m/s, the inner diameter of the outer pipe is set as D _{Inner diameter of outer pipe} The unit: mm; the length of the outer pipe is L _{Outer tube} The unit: m;

the outer diameter of the inner pipe is set as D based on the outer diameter of the external oil pipe of the pump _{Outer diameter of inner tube} The unit "mm; inner diameter of the inner tube is D _{Inner diameter of inner tube} The unit is: mm; the length of the inner tube is L _{Inner pipe} The unit: m;

the daily maximum output of the external drainage pump is set as Q, unit: m is ³ D; number of strokes is n, unit: the times are/min;

setting the aperture of the liquid inlet hole as d, unit: mm; the number of the holes is k, and the unit is one;

step S2, obtaining specification parameters of the outer pipe and the inner pipe:

taking the upward flow velocity of the liquid in the inner pipe as 2m/s to obtain:

D _{inner diameter of inner tube} ＝3.84√Q (1)

According to the calculation result of formula (1), selecting proper inner pipe in the pipe sequence, and simultaneously determining corresponding D _{Outer diameter of inner tube} ；

And obtaining the following result according to the descending flow velocity of the liquid in the inner and outer tube annular space of 0.2 m/s:

D _{inner diameter of outer pipe} ＝√(147.44Q+D _{Outer diameter of inner tube} ² ) (2)

Calculating the result according to formula (2) and using D _{Outer diameter of outer tube} Selecting a proper outer pipe in the pipe sequence under the condition that the inner diameter of the outer well casing is 6 mm;

on the basis that the aperture d of the liquid inlet hole is 8mm or 10mm, the flow speed of liquid entering the liquid inlet hole is less than 0.2m/s, and the method comprises the following steps:

k>147.44Q/d ² (3)

determining the total number of the liquid inlet holes by the multiple of the number of holes per circle according to the calculation result of the formula (3);

on the basis that the volume of the inner and outer tube annuluses is larger than the single-stroke pumping capacity of an external drainage pump, the effective separation length of the inner and outer tube annuluses is L:

L>884.6Q/n/(D _{inner diameter of outer pipe} ² -D _{Outer diameter of inner pipe} ² ) (4)

Adding the length of the liquid inlet hole arrangement section to L according to the calculation result of the formula (4) to obtain the minimum length L of the inner pipe _{Inner pipe} (ii) a Inner pipe length L _{Inner tube} + expanding nipple length + expanding nipple and lower joint clearance distance 0.2m as the minimum length L of the outer tube _{Outer tube} 。

Compared with the prior art, the manufacturing method of the shaft inner gas-liquid-solid separation device and the manufactured shaft inner gas-liquid-solid separation device have the advantages that the liquid inlet holes are formed in the upper end of the outer pipe, the inner pipe is inserted into the outer pipe, the lower end of the inner pipe is connected with the diameter-expanding short section, the annular space between the outer pipe and the inner pipe is as large as possible, the downward flowing speed of liquid is reduced to be lower than the upward floating speed of bubbles in the annular space, and the bubbles are prevented from flowing downwards along with the downward flowing liquid; the length of the outer pipe ensures that the annular volume of the inner pipe and the outer pipe is larger than the single suction volume of the external extraction pump, and bubbles upwards flow out of the annular volume of the inner pipe and the outer pipe at a higher speed in a suction interval period, so that the effect of completely separating gas from liquid is achieved, and cavitation damage of a gas lock and an oil pipe is avoided. The inner tube lower extreme is even hole enlargement nipple joint, and its overflow area is greater than row and adopts pump and upper end tubular column overflow area, and the speed that the fluid up flowed is minimum here, and great particulate matter subsides here, falls into lower extreme sand setting pipe, can be here along with the fluid up flow particulate matter that advances the pump, can not deposit on the pump, therefore avoided particulate matter card pump. The gas-liquid-solid three-phase density difference is utilized, a reasonable flowing space is set, so that the floating speed of bubbles is higher than the downward flowing speed of liquid, the sinking speed of solid particles is higher than the upward flowing speed of liquid, gas and solid particles are separated from the liquid to the maximum extent, the occurrence of gas lock or pump blocking fault of an extraction pump is avoided, the reliability of the gas-liquid-solid separation device in a shaft is effectively improved, and the service life of the gas-liquid-solid separation device in the shaft is effectively prolonged.

Drawings

In order to make the content of the invention clearer, the drawings needed to be used in the description of embodiments will be briefly described, it being clear that the drawings in the description below are only some embodiments of the invention, and that other drawings can be derived by those skilled in the art without inventive effort, wherein:

FIG. 1 is a schematic diagram of a gas-liquid-solid separation apparatus in a wellbore according to the present invention;

FIG. 2 is a block flow diagram of a method for gas-liquid-solid separation in a wellbore according to the present invention.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Referring to fig. 1, the present invention provides a separation apparatus 100 for gas, liquid and solid in a shaft, which is used between a drainage and production pump (not shown) and a sand-settling pipe (not shown) of a coal-bed gas well drainage and production equipment, wherein the separation apparatus 100 for gas, liquid and solid in a shaft comprises an oil pipe joint hoop 1, a lifting short section 2, an upper joint 3, an outer pipe 4, a liquid inlet hole 5, an inner pipe 6, an expanding short section 7 and a lower joint 8. The embodiment discharges water by day 40m ³ The gas-liquid-solid separation device matched with the drainage pump is taken as an example for detailed description:

the upper joint 2 is in a hollow ring shape, and the lower end of the upper joint 3 is provided with an outer buckle (not numbered) positioned at the outer side of the upper joint and an inner buckle (not numbered) positioned at the inner side of the upper joint.

The upper end of the outer pipe 4 is connected with the upper joint 3 through being buckled with the outer part, and the upper end of the outer pipe 4 is provided with a plurality of liquid inlet holes 5 penetrating through the outer pipe.

The inner pipe 6 is inserted into the outer pipe 4 and spaced from each other, the upper end of the inner pipe 6 is connected to the upper joint 3 through the inner buckle, and the inner pipe 6 is communicated with the upper joint 3.

The diameter-expanding short section 7 is connected to the lower end of the inner pipe 6 to be suspended in the outer pipe 4, and the diameter-expanding short section 7 and the outer pipe 4 are spaced mutually.

The inner pipe 6, the diameter-expanding short section 7 and the outer pipe 4 jointly enclose an inner pipe annulus and an outer pipe annulus, and the inner pipe annulus and the outer pipe annulus meet the preset flow area so as to realize gas-liquid separation.

In the present embodiment, specifically, the maximum theoretical displacement of the extraction pump externally connected to the gas-liquid-solid separation apparatus 100 in the wellbore is used for calculating, so that the inner diameter of the inner pipe 6 satisfies the flow rate of 2m/s, and the flow rate of the inner pipe is calculated at the maximum theoretical displacement of the extraction pump, where 2m/s is a recognized economic flow rate of general liquid. The outer diameter of the outer pipe 4 is at least 6mm smaller than the inner diameter of a shaft casing which is externally connected with the gas-liquid-solid separation device 100 in the shaft, so as to meet the requirements of downhole operation specifications.

The inner and outer tube annular space meets the floating speed of the bubbles with the maximum liquid flow velocity lower than 0.1mm in diameter, and the effect of gas-liquid separation is achieved. The annular space formed by the inner wall of the outer pipe 4 and the outer wall of the inner pipe 6 is as large as possible, the maximum flow velocity of the liquid is guaranteed to be lower than the floating velocity of bubbles with the diameter of 0.5mm by 0.2m/s, and the minimum diameter of the bubbles desorbed from the shale and the coal rock in water is about 0.5mm through laboratory observation and analysis.

The difference between the inner diameter of the outer pipe 4 and the outer diameter of the diameter-expanding short section 7 is larger than 10mm, and sufficient falling space of annular sand grains is guaranteed.

The length of the outer pipe meets the condition that the effective separation volume of the annular space of the inner pipe and the outer pipe is larger than the single-time suction volume of the drainage pump, bubbles upwards flow out of the annular space at a higher speed in a suction interval period, the effect of completely separating gas from liquid is achieved, cavitation damage of a gas lock and an oil pipe is avoided, and the reliability and the service life are effectively improved.

The flow area of the diameter-expanding short section 7 is not less than that of an externally connected upper pump oil pipe (not shown), so that the flow rate of liquid at the position of the diameter-expanding short section 7 is lower than that of liquid at any position of the externally connected upper pump oil pipe, solid particles are settled and separated from the liquid, and the effect of solid-liquid separation is achieved. Great particulate matter subsides here, falls into lower extreme sand trap, can be here along with the fluid up flow into the particulate matter of pump, can not deposit on the pump, therefore avoided particulate matter card pump. In the embodiment, the clearance distance between the lower end of the diameter-expanding short section 7 and the lower joint 8 is at least 200 mm.

The lower joint 8 is screwed to the lower end of the outer pipe 4. The lower end of the lower joint 8 is used for connecting a sand-settling pipe.

The lower end of the lifting short section 2 is inserted into the upper end of the upper joint 3, and the oil pipe joint hoop sleeve 1 is connected to the upper end of the lifting short section 2. And the upper end of the oil pipe joint hoop sleeve 1 is used for connecting a drainage pump.

The length of the lifting short section 2 is 400mm, the diameter of the lifting short section is consistent with that of an externally connected upper pumping oil pipe, and the diameter of the oil pipe joint hoop 1 is matched with that of the lifting short section 2, so that the lifting short section has the function of hoisting in a well.

The liquid inlet holes 5 are arranged downwards from the outer pipe 4 to the position 150mm away from the upper joint 3, and the aperture and the number of the liquid inlet holes 5 are designed to meet the requirement that the maximum overflowing speed of all the liquid inlet holes is lower than 0.2m/s, so that gas in the inner and outer pipe ring spaces can return to the outside of the outer pipe 4 while liquid is fed.

In the structure, the gas-liquid-solid three-phase density difference is utilized, the reasonable flowing space is set, the floating speed of bubbles is higher than the downward flowing speed of liquid, the sinking speed of solid particles is higher than the upward flowing speed of liquid, gas and solid particles are separated from the liquid to the maximum extent, the occurrence of gas lock or pump blocking faults of a drainage pump or a mining pump is avoided, and the reliability and the service life of the gas-liquid-solid separation device 100 in the shaft are effectively improved.

Referring to fig. 1-2, the present invention also provides a method for manufacturing the gas-liquid-solid separation device in a shaft according to the present invention.

The coal bed gas drainage and production is oil pipe drainage, and the oil sleeve annulus generates gas. In the air flow of the oil jacket ring, the air is influenced by the quick upward flow of the air body of the oil jacket ring, various complex flow states such as turbulent flow, circular flow, fog flow and the like can occur due to different gas-liquid ratios and different flow rates, and the gas and the liquid can be mixed together with any granularity. Once the liquid mixed with gas and solid enters the inner and outer tube annuluses of the gas-liquid-solid separator, the liquid is no longer influenced by the upward gas flow in the oil sleeve annulus, and small bubbles are quickly gathered into large bubbles, float on the upper parts of the inner and outer tube annuluses and return to the oil sleeve annulus.

Laboratory observation and analysis show that the minimum diameter of bubbles desorbed from shale and coal rock in water is about 0.5mm, and the floating speed is 0.2 m/s; the larger the diameter of the bubbles, the higher the floating speed. Therefore, the floating speed of bubbles of 0.2m/s is taken as a design basis, and the specific size calculation design of the gas-liquid-solid separation device is realized: the inner diameter of the outer pipe, the outer diameter of the inner pipe, the aperture and the number of the liquid inlet holes and the lengths of the inner pipe and the outer pipe are mainly designed.

The water is drained by 40m day ³ The gas-liquid-solid separator matched with the drainage pump is taken as an example, and the method comprises the following steps:

step S1, designing specification parameters of the outer tube 4 and the inner tube 6:

typically the production casing has an internal diameter of 124mm and so an outer tube 4 of suitable size is selected at 118mm and below. Based on the floating speed of the bubbles of the leaf being 0.2m/s, the inner diameter of the outer tube is set as D _{Outer tubeInner diameter} The unit is: mm; the length of the outer pipe is L _{Outer tube} The unit is: and m is selected.

The outer diameter of the external pump oil pipe is set as D _{Outer diameter of inner tube} The unit "mm; inner diameter of the inner tube is D _{Inner diameter of inner tube} The unit is: mm; the length of the inner tube is L _{Inner pipe} The unit is: and m is selected. The production tubing typically has an outer diameter of 73mm and so an appropriately sized inner tubing 6 is selected at 73mm and below.

The maximum daily liquid production theoretical displacement of an external drainage pump is set as Q, unit: m is a unit of ³ D; the number of strokes is n, unit: every minute;

the aperture of the liquid inlet hole 5 is d, unit: mm; the number of holes is k, unit: piece.

(1) taking the upward flow velocity of the liquid in the inner pipe 6 as 2m/s to obtain:

D _{inner diameter of inner tube} ＝3.84√Q (1)

According to the calculation result of the formula (1), selecting a proper inner pipe 6 in the pipe sequence, and simultaneously determining the corresponding D _{Outer diameter of inner pipe} ；

(2) And obtaining the following result according to the liquid descending flow velocity in the inner and outer tube annular space of 0.2 m/s:

D _{inner diameter of outer pipe} ＝√(147.44Q+D _{Outer diameter of inner pipe} ² ) (2)

Calculating the result according to formula (2) and using D _{Outer diameter of outer tube} Selecting a proper outer pipe 4 in the pipe sequence under the condition that the inner diameter of the outer well casing is 6 mm;

(3) on the basis that the aperture d of the liquid inlet hole 5 is 8mm or 10mm, the flow speed of liquid entering the liquid inlet hole is less than 0.2m/s, and the method comprises the following steps:

k>147.44Q/d ² (3)

determining the total number of the liquid inlet holes 5 by the multiple of the hole number per circle according to the calculation result of the formula (3);

(4) on the basis that the volume of the inner and outer tube annuluses is larger than the single-stroke-time pumping capacity of an external extraction pump, the effective separation length of the inner and outer tube annuluses is obtained as L:

L>884.6Q/n/(D _{inner diameter of outer pipe} ² -D _{Outer diameter of inner tube} ² ) (4)

Adding the length of the liquid inlet hole arrangement section to L according to the calculation result of the formula (4) to obtain the minimum length L of the inner pipe _{Inner tube} (ii) a Inner pipe length L _{Inner tube} + expanding nipple length + expanding nipple and lower joint clearance distance 0.2m as the minimum length L of the outer tube _{Outer tube} 。

According to the method, the water is drained by 40m day ³ The gas-liquid-solid separator matched with the extraction pump is taken as an example, and the gas-liquid sharing device in the well cylinder in the embodiment is as follows: the outer diameter of the inner tube is 36mm, the inner diameter of the inner tube is 28mm, and the length of the inner tube is 5.6 m; the length of the expanding short section is 215mm, the inner diameter of the expanding short section is 62mm, and the outer diameter of the expanding short section is 73 mm. The outer diameter of the outer pipe is 101.6mm, the inner diameter of the outer pipe is 88.3mm, the diameter of the liquid inlet hole is 10mm 6 x 11 (6 holes are uniformly distributed on each annular section, 6 holes are distributed after staggered by 30 degrees at intervals of 40mm, and the total number of the holes is 66) and the length of the outer pipe is 6m (the effective length of annular gas-liquid separation is ensured to be larger than 3.6 m). The lifting nipple and the oil pipe joint hoop are consistent with an external oil pipe with the external diameter of 73mm, and the lifting nipple is 400mm long.

When the device is used, the upper part of the gas-liquid sharing device in the shaft is connected with the drainage pump, and the lower part of the gas-liquid sharing device in the shaft is connected with the sand settling pipe and goes down to the designed well depth. After the drainage pump is pumped, the gas-liquid-solid separation device automatically plays a role, liquid enters the inner pipe annulus and the outer pipe annulus from the oil sleeve annulus through the liquid inlet hole 5 of the outer pipe 4, flows downwards, turns to the diameter-expanding short section 7, flows upwards, and enters the pump suction valve through the inner pipe 6 and the lifting short section 2; the gas is separated from the liquid in the inner and outer pipe annular space and returns to the oil sleeve annular space; solid particles are settled at the diameter-expanding short section 7 and enter the sand settling pipe. After the deposition of solid particles in the sand setting pipe is slow, when the pump discharge capacity is reduced, the pipe lifting column can clean the sand setting pipe, no other operation is needed in the operation process, the use is convenient, and the reliability is good.

Compared with the prior art, the manufacturing method of the shaft inner gas-liquid-solid separation device and the manufactured shaft inner gas-liquid-solid separation device have the advantages that the liquid inlet holes are formed in the upper end of the outer pipe, the inner pipe is inserted into the outer pipe, the lower end of the inner pipe is connected with the diameter-expanding short section, the annular space between the outer pipe and the inner pipe is as large as possible, the downward flowing speed of liquid is reduced to be lower than the upward floating speed of bubbles in the annular space, and the bubbles are prevented from flowing downwards along with the downward flowing liquid; the outer tube length is greater than external row and adopts the pump single suction volume in order to guarantee that interior outer tube annular space volume, and in the suction interval period, the bubble up flows out interior outer tube annular space with faster speed, plays the effect of gas-liquid thorough separation, avoids airlock and oil pipe cavitation to damage. The diameter-expanding nipple joint is connected to the lower end of the inner pipe, the overflowing area of the inner pipe is larger than that of the discharging and extracting pump and the upper end pipe column of the discharging and extracting pump, the upward flowing speed of fluid is lowest at the position, large particles are settled at the position and fall into the lower end sand settling pipe, the particles entering the pump along with the upward flowing of the fluid can not be settled on the pump at the position, and therefore the particles are prevented from being stuck on the pump. Utilize gas-liquid-solid three-phase density difference, set up reasonable flow space, make bubble floating velocity be faster than liquid downflow velocity, solid particle sinking velocity is faster than liquid upflow velocity, furthest separates out gas, solid particle from liquid, avoids the emergence of drainage pump gas lock or card pump trouble, the effectual gas-liquid-solid separator's in the pit shaft reliability and life that have improved.

The above examples are merely illustrative for clearly illustrating the present invention and are not intended to limit the embodiments; the scope of the present invention includes, but is not limited to, the above embodiments, and all equivalent changes in the shape and structure of the present invention are included in the scope of the present invention.

Claims

1. A gas-liquid-solid separation device in a shaft is applied between a discharge and production pump and a sand setting pipe of coal bed gas well discharge and production equipment and is characterized by comprising an oil pipe joint hoop, a lifting short section, an upper joint, an outer pipe, a liquid inlet hole, an inner pipe, an expanding short section and a lower joint;

the inner pipe, the expanding short section and the outer pipe together enclose an inner pipe annulus and an outer pipe annulus, and the inner pipe annulus and the outer pipe annulus meet a preset overflowing area so as to realize gas-liquid separation;

2. The gas-liquid-solid separation device in the shaft according to claim 1, wherein the liquid inlet holes are arranged from the outer pipe to the upper joint in a distance of 150mm downwards, and the aperture and the number of the liquid inlet holes are designed to meet the requirement that the maximum overflowing speed of all the liquid inlet holes is lower than 0.2 m/s.

3. The apparatus for gas-liquid-solid separation in a wellbore of claim 1, wherein the inner and outer tubular annulus satisfies a predetermined flow area, comprising:

the inner and outer tube annular space meets the floating speed of the bubbles with the maximum liquid flow rate lower than 0.1mm in diameter;

4. The apparatus of claim 1, wherein the lower end of the expanding sub has a clearance of at least 200mm from the lower sub.

5. The apparatus for gas-liquid-solid separation in a wellbore of claim 1, wherein the upper joint is terminated with a hoisting sub and a tubing coupling, comprising:

6. A method of manufacturing a gas-liquid-solid separation device in a wellbore according to claim 1, the method comprising the steps of:

based on the floating speed of the bubbles of the leaf being 0.2m/s, the inner diameter of the outer tube is set as D _{Inner diameter of outer pipe} The unit: mm; the length of the outer tube is L _{Outer tube} The unit is: m;

the outer diameter of the external pump oil pipe is set as D _{Outer diameter of inner tube} The unit "mm; inner diameter of the inner tube is D _{Inner diameter of inner tube} The unit: mm; the length of the inner tube is L _{Inner tube} The unit is: m;

the maximum daily liquid production theoretical displacement of an external drainage pump is set as Q, unit: m is ³ D; the number of strokes is n, unit: every minute;

and setting the aperture of the liquid inlet hole as d, unit: mm; the number of the holes is k, and the unit is one;

step S2, obtaining specification parameters of the outer tube and the inner tube:

D _{inner diameter of inner tube} ＝3.84√Q (1)

Calculating the result according to formula (2) and calculating by D _{Outer diameter of outer tube} Selecting a proper outer pipe in the pipe sequence under the condition that the inner diameter of the outer well casing is 6 mm;

k>147.44Q/d ² (3)

determining the total number of the liquid inlet holes by the multiple of the number of holes in each circle according to the calculation result of the formula (3);

L>884.6Q/n/(D _{inner diameter of outer tube} ² -D _{Outer diameter of inner pipe} ² ) (4)

Adding the length of the liquid inlet hole arrangement section to L according to the calculation result of the formula (4) to obtain the minimum length L of the inner pipe _{Inner tube} (ii) a Inner pipe length L _{Inner pipe} The sum of the length of the diameter-expanding short section and the clearance distance between the diameter-expanding short section and the lower joint is 0.2m, and the minimum length L of the outer pipe is taken as _{Outer tube} 。