CN214576923U - Coal bed gas horizontal well system - Google Patents

Abstract

The utility model discloses a coal bed gas horizontal well system, which comprises a horizontal well group, wherein the horizontal well group comprises a first horizontal well track and a second horizontal well track, the first horizontal well track is positioned on the lower bottom plate of the coal bed with relatively stable geological structure, and the second horizontal well track is positioned on the upper top plate of the coal bed with relatively stable geological structure; the first horizontal well track is in an inverted L shape, and the first horizontal well track is connected with the second horizontal well track to form an inverted F-shaped horizontal well group. The utility model provides high coal bed gas is to the development efficiency of structure coal, low order coal, has avoided the well wall of a well of coal bed gas horizontal well to collapse and the problem that the seepage flow passageway blockked up, makes coal bed gas horizontal well development process more steady reliable to have the effect that improves drilling construction in earlier stage and later maintenance nature operating efficiency.

Description

Coal bed gas horizontal well system

Technical Field

The utility model relates to an underground fluid resource exploitation technical field especially relates to a coal bed gas horizontal well system.

Background

Coal bed gas is usually mined by adopting a vertical well, a directional well and a horizontal well, common horizontal well processes are divided into a single main branch horizontal well, two main branch multi-branch horizontal wells, a single main branch lower PE pipe multi-branch horizontal well, a multi-stage fracturing U-shaped horizontal well and a slave multi-stage fracturing horizontal well, and the common goals of various mining modes are to improve the coal bed gas mining efficiency and increase the input-output ratio.

Due to the diversity of coal bed geological conditions in different areas of China and the different high, medium and low coal rank contents of each block, the mining effect is greatly different. At present, the tectonic coal and the low-rank coal accounting for 80 percent of the tectonic coal are still in an inefficient development state, namely the input-output ratio is poor.

The main problems are: first, the production efficiency of a vertical well and a directional well is low. Secondly, the conventional horizontal well process has poor stability of a well hole in a coal bed of low-rank coal and constructional coal, is easy to collapse, and is easy to cause complex accidents such as well leakage, collapse, drilling sticking and the like. Third, even if the wellbore is completed well, drilling mud (including degradable mud, due to lost circulation) can block the coalbed methane seepage channels. Fourthly, drilling in the coal seam, namely, the gas leakage area is increased by depending on the drilling rate of the coal seam, and once the drilling rate of the coal seam is low, the influence on the later-period coal bed gas yield is very large; the coal seam penetration rate refers to the ratio of the penetration to the total penetration in the coal seam. Fifthly, the coal seam track has great influence on drainage and mining; along with the change of the coal seam inclination angle, grooves are easy to form in some well sections, and water plugs are formed during production, drainage and mining. When structural coal exists at the bottom of the coal seam and is drilled, coal ash is gathered at the groove, so that ash blockage is caused during drainage and mining, and high yield is not facilitated. And sixthly, the low permeability and broken coal quality of the low-order coal bed cause low gas production rate or no gas production of the coal bed gas well.

The main contradictions in the actual coal bed gas exploitation process are that the drilling accidents of low-rank coal are more, the drilling period is long, the coal bed drilling rate of a thin coal bed is low, the mud pollution of a target coal bed is serious, the fracturing effect is poor, the cost is high, the drilling cost of a horizontal well is in direct proportion to the drilling footage, the coal bed gas exploitation effect is very low, and the input and output are poor.

The patent document with the publication number of CN101956548B provides a coal bed gas multi-branch horizontal well system which can improve the exploitation area and the exploitation efficiency of a multi-branch horizontal well under the condition that the floor area of the horizontal well is not increased. However, in the scheme provided by the patent, the horizontal well is drilled in a coal seam, the problem of borehole wall collapse of low-rank coal still cannot be solved, and along with the prolonging of the mining time, the seepage channel is gradually blocked, so that the problem of low gas production or no gas production in the later period is caused, and the actual mining efficiency is not high.

SUMMERY OF THE UTILITY MODEL

The utility model provides a coal bed gas horizontal well system has the development efficiency that improves the coal bed gas to structure coal, low order coal, has avoided the well wall of a well of the coal bed gas horizontal well to collapse and the problem that the seepage flow channel blockked up, makes coal bed gas horizontal well development process more steady reliable to have the effect that improves drilling construction in earlier stage and later maintenance nature operating efficiency. The specific technical scheme is as follows:

a coal bed gas horizontal well system comprises a horizontal well group, wherein the horizontal well group comprises a first horizontal well track and a second horizontal well track, the first horizontal well track is positioned on a lower bottom plate of a coal bed with a relatively stable geological structure, and the second horizontal well track is positioned on an upper top plate of the coal bed with a relatively stable geological structure; the first horizontal well track is in an inverted L shape, and the first horizontal well track is connected with the second horizontal well track to form an inverted F-shaped horizontal well group.

Further, the first horizontal well track comprises a vertical section, a bending section and a horizontal section, and the vertical section penetrates through the upper coal seam roof, the coal seam and the lower coal seam floor; the horizontal section is arranged on a lower bottom plate of the coal seam and is parallel to the coal seam, and the distance between the horizontal section and the lower boundary of the coal seam is 0.2-2.0 m; two ends of the bending section are respectively connected with the vertical section and the horizontal section.

Further, the vertical section is provided with a surface casing, and the bending section and the horizontal section are provided with production casings to the bottom of the well to form a first horizontal well.

Further, the vertical section and the bending section are provided with cement layers to seal the first horizontal well.

Further, a first horizontal well is connected with the coal seam through at least one first perforation, and the first horizontal well can perform hydraulic jetting or small fracturing and seam making on the coal seam through the first perforation to form a drainage and exhaust channel.

Further, an oil pipe is arranged on the lower boundary of the coal bed to conduct drainage, depressurization and gas production.

Further, the second horizontal well trajectory comprises a windowed sidetracking point and a horizontal segment, and a production casing is arranged from the windowed sidetracking point to the bottom of the well to form a second horizontal well.

Furthermore, the horizontal section of the second horizontal well is parallel to the coal seam, and the distance between the horizontal section of the second horizontal well and the upper boundary of the coal seam is 0.2-2.0 m.

Furthermore, a second horizontal well is connected with the coal seam through at least one second perforation, and the second horizontal well can perform large-scale staged fracturing or dragging fracturing on the coal seam through the second perforation so as to form cracks in the coal seam.

Furthermore, support sand is arranged in the crack of the coal bed to form a low-order coal bed gas channel and increase the seepage channel of the coal bed gas.

The horizontal branch well is constructed in the upper bottom plate and the lower bottom plate of the target coal bed, as the upper top plate and the lower bottom plate of the low-order coal bed and the structural coal bed are mostly sand shale or metamorphic rock, the stability is better relative to the coal bed, and various mud systems can be used in the drilling process without polluting the target layer; the horizontal well drilling tool can effectively avoid the complex conditions of well leakage, coal bed collapse and the like of a well bore of the horizontal well in the well drilling process, can also use more advanced near-drill bits and rotary steering instruments in China to accelerate the construction progress, and promotes the development of domestic directional instruments and levels.

The natural filtering barrier for low-rank coal ventilation is formed by fracturing and seam making of the upper top plate in a large scale, so that the problem that a low-rank coal bed methane seepage channel is easy to block is solved; through lower plate hydraulic jet or small-size fracturing joint-making, for the permeable to water depressurization creation condition of low order coal, can prevent moreover that the buggy from excessively adopting, through the drainage depressurization gas production of vertical shaft realize the high-efficient exploitation of low order coal bed gas. The utility model discloses a separation of drainage and gas production has improved row and has adopted efficiency.

The above description is only an overview of the technical solutions of the present invention, and in order to make the technical means of the present invention more clearly understood, the present invention may be implemented according to the content of the description, and in order to make the above and other objects, features, and advantages of the present invention more obvious and understandable, the following detailed description of the present invention is given.

Drawings

Various other advantages and benefits will become apparent to those of ordinary skill in the art upon reading the following detailed description of the preferred embodiments. The drawings are only for purposes of illustrating the preferred embodiments and are not to be construed as limiting the invention. Also, like reference numerals are used to refer to like parts throughout the drawings. In the drawings:

fig. 1 is a schematic diagram of a first horizontal well trajectory landing segment of the coal bed gas horizontal well system of the present invention;

fig. 2 is a schematic diagram of a first horizontal well trajectory of the coal bed gas horizontal well system of the present invention;

fig. 3 is a schematic view of a second horizontal well trajectory casing windowing of the coal bed gas horizontal well system of the present invention;

figure 4 is the utility model discloses a second horizontal well orbit sketch map of coal bed gas horizontal well system.

Detailed Description

In order to better understand the purpose, function and specific design scheme of the present invention, the coal bed gas horizontal well system of the present invention is described in further detail below with reference to the accompanying drawings.

As shown in fig. 1-4, the coal bed gas horizontal well system of the present invention comprises a horizontal well group, wherein the horizontal well group comprises a first horizontal well track 1 and a second horizontal well track 2, and the positions of the first horizontal well track 1 and the second horizontal well track 2 are located on a lower coal bed bottom plate 3 and an upper top plate 2 with relatively stable geological structures; the first horizontal well track 1 is of an inverted L shape, and the first horizontal well track 1 is connected with the second horizontal well track 2 to form an inverted F-shaped horizontal well group.

Specifically, a first horizontal well track 1 is arranged on a lower bottom plate 3 of a coal seam, a second horizontal well track 2 is arranged on an upper top plate 2 of the coal seam, wherein the second horizontal well track 2 is a casing windowing well or a side drilling well; the second horizontal well track 2 is subjected to large-scale fracturing and serves as a gas producing well; the first horizontal well trajectory 1 is subjected to small fracturing, which acts as a drainage well, differentiated for use according to actual geological conditions.

The first horizontal well track 1 comprises a vertical section, a bending section and a horizontal section, wherein the vertical section penetrates through an upper coal seam roof, a coal seam and a lower coal seam floor; the horizontal section is arranged on a lower bottom plate of the coal seam and is parallel to the coal seam, and the distance between the horizontal section and the lower boundary of the coal seam is 0.2-2.0 m; two ends of the bending section are respectively connected with the vertical section and the horizontal section. The vertical section is provided with a surface casing, and the bending section and the horizontal section are provided with production casings to the bottom of the well so as to form a first horizontal well. The vertical section and the bending section are provided with cement layers to seal the first horizontal well. The first horizontal well is connected with the coal bed through at least one first perforation, and the first horizontal well can perform hydraulic jetting or small fracturing and seam making on the coal bed through the first perforation to form a drainage channel and an exhaust channel. And an oil pipe is arranged at the lower boundary of the coal bed to perform drainage, depressurization and gas production.

The second horizontal well trajectory 2 comprises a windowed sidetracking point and a horizontal section, the windowed sidetracking point to the bottom of the well being provided with a production casing to form a second horizontal well. The horizontal section of the second horizontal well is parallel to the coal seam and is 0.2-2.0 m away from the upper boundary of the coal seam. The second horizontal well is connected with the coal bed through at least one second perforation, and the second horizontal well can perform large-scale staged fracturing or dragging fracturing on the coal bed through the second perforation so as to form cracks in the coal bed. And supporting sand is arranged in the crack of the coal bed to form a low-order coal bed gas channel and increase a coal bed gas seepage channel.

It is right according to the construction order below the utility model discloses a coal bed gas horizontal well system introduces.

Firstly, a low-rank coal seam or a structural coal seam is selected for reconstruction, and the thickness of the coal seam is 1.5-8.0 m.

Secondly, drilling a lower bottom plate 3 of a target coal seam through a first horizontal well track 1, and then drilling for 300-2000 m along the horizontal direction according to the coal seam track; the distance between the first horizontal well track 1 and the lower boundary of the target coal seam is 0.2-2.0 m.

And thirdly, selectively placing 5-half-7 inch technical sleeves 10-20 m after the track 1 from the wellhead to the first horizontal well enters the bottom plate 3.

And fourthly, cementing the first horizontal well track 1 by using cement.

Fifthly, windowing and sidetracking a second horizontal well track 2 at the position of a target coal seam boundary and a well inclination angle of 45-75 degrees by the first horizontal well track 1, and then drilling for 300-2000 m along the horizontal direction, wherein the distance between the second horizontal well track 2 and the target coal seam upper boundary is also 0.2-2.0 m. Notably, this approach may also be used to retrofit low production horizontal wells that are not fractured.

And sixthly, respectively setting 4-5 inches of semi-productive casing pipes from the horizontal section of the first horizontal well track 1 to the bottom of the well and from the windowing sidetracking point of the second horizontal well track 2 to the bottom of the well to form the first horizontal well and the second horizontal well.

And seventhly, performing directional perforation downwards on the second horizontal well, and performing large-scale staged fracturing or dragging fracturing on the second horizontal well.

And eighthly, performing directional perforation upwards in the first horizontal well, and performing hydraulic jetting or small fracturing and seam making in the first horizontal well.

And ninthly, lowering the oil pipe to the lower boundary of the coal bed gas to perform drainage and depressurization gas production.

The construction sequence is described in detail below with specific examples

Example one

As shown in fig. 1, horizontal well one-shot (i.e., vertical section of first horizontal well trajectory 1) uses a d311.2mm roller cone drill bit, drill assembly: phi 311.15mmPDC + phi 177.8mmX/O + phi 177mmDC + phi 165mmX/O + phi 127mm DP, drilling the rock-soil slurry drilling fluid at the well depth of 60-80m after the rock-soil slurry drilling fluid drills through a bed rock weathering zone for 20m, and completely sealing the lower D244.5mm surface casing by injecting cement.

Horizontal well two (i.e. the bending section of the first horizontal well track 1) uses a D215.9mm drill bit, and the drilling tool assembly: phi 215.9mmPDC + phi 172mm 1.5 DEG Motor + phi 172mmFV + phi 172mmUBHO + phi 172mmNMDC + phi 127mmDP + phi 127 mmHWDP; and drilling the coal seam through the target coal seam at a 90-98-degree well inclination angle, drilling the coal seam at 0.2-2.0 m below the target coal seam for 10-20 m, then tripping the coal seam, running a D177.8mm production casing for well cementation, cementing, sealing, and returning cement slurry to 200m above the top of the target coal seam. The main function of the second-order switch is to determine the destination layer and complete the landing.

As shown in fig. 2, horizontal well three openings (i.e., horizontal section of first horizontal well trajectory 1) used a d152.4mm drill bit, near bit instrumentation drill assembly: phi 152.4mm PDC + phi 120mm NearBitSub + phi 120mm Motor (1.50Deg.) + phi 120mmF/V + phi 120mm UBHO + phi 120mm NMDC +127mm GAP + phi 120mm NMDC + phi 89mm DP, a near-bit instrument is recommended for a stratum with stable geological conditions, the total cost is low, the mechanical drilling speed is high, the period is short, the coal seam trend can be followed quickly and stably, and a conventional EM instrument or a rotary steering instrument can be used according to the geological conditions; and constructing a first horizontal well track 1 along the horizontal direction according to the coal seam trend, drilling a single branch for 300-2000 m, putting a D114mm production casing pipe into the well bottom for no more than 20-50 m, and hanging the top of the casing pipe in a position 10-20 m above a D177.8mm casing shoe.

The main functions of the first horizontal well trajectory 1 are: the casing is put in, the problems of collapse of the coal bed of the main well of the coal bed gas horizontal well and blockage of a gas production channel are solved through small-sized fracturing, a stable coal bed gas multi-branch horizontal well development drainage and ash removal channel is established on the coal bed bottom plate 3 with stable geological conditions, and a stable well hole environment is provided for well drilling construction and later maintenance operation.

A fishable slope setter is arranged 2-5 m below the windowing position, so that rock debris is prevented from entering a first horizontal well track 1; the windowing drilling tool combination is replaced after the drilling is finished, and casing windowing operation is performed at a well inclination angle of 45-75 degrees as shown in figure 3; after the tool is lowered to a cutting position, the rotary table or the top drive is started, and after the drill stem rotates normally, the drilling pump can be started to pump drilling fluid into the drill stem. After cutting the casing, the tool was rotated for 10 minutes to trim the cut section. And then, trial drilling pressure is added, the drilling pressure can be added, the successful cutting is proved, the forging and milling operation can be carried out under pressurization, and the change of torque and the drilling jump condition are closely observed in the forging and milling process. If the phenomenon of drill jumping occurs, the rotating speed and the drill pressure can be reduced, so that the tool works stably. And after the normal state is recovered, gradually recovering the original bit pressure and the original rotation speed to find the optimal working parameters. In the forging and milling process, a specially-assigned person is dispatched to observe the condition of the returned substances in the drilling fluid at the vibrating screen to judge whether the forging and milling is finished or not, once the forging and milling of the casing is expected to be complete, the drilling is determined to stop, the drilling fluid is circulated for one week, and the well hole is cleaned. And then, pulling the drill, slowly lifting the drilling tool before the tool enters the casing pipe to enable the drilling tool to smoothly enter the casing pipe, and then pulling the drill at a normal speed.

After windowing is finished, according to the known first horizontal well track 1 and coal seam data, a D152.4mm drill bit is used for drilling in a direction of 300-2000 m along the target coal seam upper boundary distance of 0.2-2.0 m and the first horizontal well track 1 to finish a second horizontal well track 2, a D114mm production casing is put to the bottom of the well, the distance is not more than 20-50 m, the top of the casing is hung at a windowing sidetracking point, and a whipstock is fished to complete the well.

The main functions of the second horizontal well trajectory 2 are: and (3) putting a casing, solving the problems of collapse of the coal bed and blockage of a gas production channel of the main well hole of the coal bed gas horizontal well through scale fracturing, and establishing a stable coal bed gas multi-branch horizontal well development gas production channel on the coal bed top plate 2 with stable geological conditions to provide a stable well hole environment for drilling construction and later maintenance operation.

Example two

And (3) once the horizontal well is opened (namely the vertical section of the track 1 of the first horizontal well), a D311.2mm roller bit is used, after a bedrock weathering zone is drilled through by 20m, the well is completely drilled at the well depth of 60m, a D244.5mm surface casing pipe is arranged, and a surface loose layer and a gravel layer are sealed. The depth of the lower part is 58m, and the lower part is sealed by cement.

Two openings (i.e. the bent section and the horizontal section of the first horizontal well track 1) use a d215.9mm drill bit, and the drilling tool assembly: phi 215.9mm PDC + phi 172mm 1.5 ° Motor + X/O + phi 172mmFV + phi 172mmUBHO + phi 172mmNMDC + NMDC + GAP + NMDC + phi 127mmHWDP + phi 127 mmDP; and (3) accelerating the mechanical drilling speed by using a near-bit instrument or a rotary steering instrument, drilling through a target coal bed at a 90-98-degree well inclination angle and keeping the drilling depth at 0.2-2.0 m below the target coal bed for drilling 300-2000 m to complete the first horizontal well track 1, then tripping in a D177.8mm production casing, cementing and cementing, wherein cement slurry returns to 200m above the top of the target coal bed.

A fishable slope setter is arranged 2-5 m below the windowing position, so that rock debris is prevented from entering a first horizontal well track 1; the windowing drilling tool combination is replaced after the drilling is finished, and casing windowing operation is carried out at a well inclination angle of 45-75 degrees; after windowing is finished, according to the known first horizontal well track 1 and coal seam data, a D152.4mm drill bit is used for drilling 300-2000 m along the direction of the horizontal well 2 along the upper boundary distance of a target coal seam to finish the second horizontal well track 2, a D114mm production casing pipe is put into the well bottom until the bottom of the well is not more than 20-50 m, the top of the casing pipe is hung on a windowing sidetracking point, and a whipstock is fished to complete the well.

Compared with the scheme 1 in the scheme 2, the scheme 2 is a double-opening well completion scheme, and has the advantages of large drill bit, increased difficulty, lower drilling speed and long construction period. However, the larger the well bore, the larger the contact area with the formation, and the more the selection of various tools and production pumps.

The method for carrying out large-scale staged fracturing or dragging fracturing on the second horizontal well track 2 comprises the following steps: the method comprises the steps of firstly carrying out directional perforation downwards on an upper horizontal well, then carrying out scale staged fracturing or dragging fracturing, wherein the upper bottom plate 3 is sandstone or metamorphic rock and is hard in texture, fracturing fluid is used for making seams between the upper top plate 2 and a low-order coal bed, fracturing is carried out through perforations of the directional perforation, fractured support sand can enter the low-order coal bed for a certain distance, an effective channel of low-order coal bed gas is further formed, and a seepage channel of the coal bed gas is increased.

Specifically, pumping bridge plug clustering perforation is carried out on a target layer in sections of 60-80m, a channel between a shaft and the target layer is established, a perforating gun is taken out after perforation for fracturing construction, a milling tool is put in after all fracturing is completed to drill and mill the bridge plug, and then a pump is put in.

The perforation requirements are as follows:

1. and preferably, correspondingly perforating the reservoir section with good reservoir physical properties.

2. And multiple clusters of perforation are distributed as dispersed as possible, so that the possibility of cracking of new cracks is increased.

3. The total length of the perforation clusters constructed in the same string is adapted to the length of the blowout preventer.

4. Avoiding the interval with poor cementing quality and casing joint hoops (adjusting after measuring the cementing quality and correcting depth).

5. According to the horizontal drilling situation, each section is divided into 3 perforation clusters, 1 m/cluster and 8 holes/m (1 m gun is used on site, and the perforation gun is loaded with 8 shots).

Technical performance of perforating gun

Model of perforating gun	Withstand voltage (MPa)	Hole density (hole/m)	Phase (°)
				89	105	8	Horizontal down 60

Performance of perforating charge

Type of perforating bullet	Temperature resistance/time (DEG C/h)	Medicine loading amount (g/hair)	Perforation aperture (mm)	Average penetration depth (mm)
					DP36RDX23	120/48	23	8.6	635

Equipment and tool parameter table

Serial number	Name (R)	Main performance parameters	Number of
				1	Logging truck	Length × height × width: 9.0 m.times.2.05 m.times.3.2 m; 7350Kg of front shaft, 15000Kg of rear shaft and 22350Kg of total assembly mass.	1 table
2	Coaxial cable	8mm of outer diameter, single core + shielding layer, 175 ℃ of temperature resistance and 105MPa of pressure resistance	7000m
				3	Crane	50T, 40m dead man	1 table
4	CCL magnetic locator	Bearing pressure of 105MPa, resisting temperature of 175 ℃,	2 pieces of
				5	Bridge plug setting tool	Baker 20 external diameter 93mm, temperature resistance 175 ℃, withstand voltage 105MPa	1 count
6	Ignition head of bridge plug tool	The outer diameter is 89mm, the temperature resistance is 175 ℃, and the pressure resistance is 105MPa	2 are provided with
				7	Multi-stage ignition head	Bearing pressure of 105MPa, resisting temperature of 175 ℃, and outer diameter of 89mm, and can realize 40-grade selective ignition	3 sets of
8	Grease injection sealing head	Sealing 8mm cable with sealing pressure of 70MPa	1 set of
				9	Blowout prevention pipe	Internal diameter of 130mm and pressure resistance of 70MPa	20m
10	Cable blowout preventer	The inner diameter is 130mm, the pressure resistance is 70MPa,8mm cable flashboard	1 set of
				11	Trap device	Internal diameter of 130mm and pressure resistance of 70MPa	1 set of
12	Pressure test pump	The highest output pressure is 105MPa	2 sets of
				13	Air station	5 square/min	1 table
14	Conversion flange	Flange-rotating lubricator union	2 are provided with

And (3) perforation construction working procedure:

1. after the perforating team arrives at the well, the responsible person first checks the well number and confirms with the field technician that the well site can be accessed at the back.

2. The responsible person of the perforating team and the field technician carefully check the relevant data and notice of the well, and fill the relevant parties mutually to inform the bookmark word identification after confirming that no mistake exists.

3. And organizing a president, arranging risk control measures according to the evaluation of well site environment and the well construction risk factors, putting responsibility to people, and designating an emergency escape route and a gathering point.

4. Blowout preventer for installing cable and grease injection control head

5. Connecting lubricator

6. Installation isolation short joint

7. Setting tool for installing bridge plug

8. Mounting electronic switches

9. Tool string integral connection

10. Installation lubricator hoist device and sealed control pipeline

11. Mounting ground pulley

12. Hoisting blowout preventer string

13. Ground connection auxiliary device

14. Wax-cleaning gate

15. Pulling-down tool, setting bridge plug and multi-shower jet hole

(1) Checking to confirm that the relative positions of the cable, the metering wheel and the ground pulley are correct.

(2) A full-open paraffin removal gate and an anti-falling gate plate.

(3) And operating the winch to slowly lower the perforating gun string, and recovering the anti-falling flashboard to be in a closed state after the tool string passes through the anti-falling flashboard.

(4) And (4) starting to descend the well at a lower speed, opening the software to perform the function test of the perforating equipment when the tool is lowered to a position 70m away from the well head, and continuing to descend after the condition is confirmed.

(5) The lowering speed of the cable is 600m/h when the well depth is more than 100m, the pump is started to discharge capacity of 0.5 square/min when the well depth reaches 400m, and the cable speed is slowly increased once the tension of the cable is increased.

(6) When the preset depth is reached, the operator needs to be informed to the pump truck 100m in advance, the pump truck is informed to prepare for stopping the pump 10m in advance, and the pump is informed to stop 5m in advance; the winch reduces the cable speed while informing the pump truck of preparing to stop the pump, and stops the pump immediately when the pump pressure is reduced once the winch is seen to stop the pump.

(7) And lifting the cable to perform well logging, measuring the lifting value from the standard coupling, and stopping when the lifting value is consistent with the calculated lifting value.

(8) The depth is confirmed again by field personnel A after the depth is correct, and after the depth is confirmed, an operator gives a signal to the underground instrument through software and a ground ignition panel to excite an ignition seat to seal a bridge plug. The method comprises the following steps: when the ignition seat seals the bridge plug, a special person is arranged at the well mouth for monitoring, and other irrelevant persons are far away from the well mouth.

(9) The software shows that the ignition is successful, the winch control panel shows that the tension changes by about 100kg, and the well head monitoring personnel obviously feel that the cable has vibration, which indicates that the bridge plug is seated. The method comprises the following steps: the bridge plug seating position should be a minimum of 10m from the front and rear perforation segments to ensure successful seating and reliable sealing.

(10) After the bridge plug is successfully set, the tool string is lifted up at the speed of 300m/h, and the speed can be accelerated only after 40m, but the speed cannot exceed 3000 m/h.

(11) And in the process of lifting the tool string to the perforation position, the CCL measures a collar curve and measures the point index difference.

(12) When measuring and positioning, the measuring and positioning speed should be less than 1000 m/h, and the error of the upward lifting value should be less than +/-0.05 m.

(13) The operator checks whether the coupling depth and the casing length are matched with the after-casing-magnetic curve diagram, and the error between the coupling depth and the casing length is +/-0.1 m.

(14) And after the perforation depth is confirmed to be correct, the depth is confirmed again by the personnel on the site A, and the operator can ignite after agreement.

(15) The software shows that the ignition is successful, the winch control panel shows that the tension changes by about 100kg, and the well head monitoring personnel obviously feel that the cable has vibration, which indicates that the perforating gun is detonated.

(16) In the process of lifting the cable, when the depth is more than 500m, the lifting speed is controlled within 4000m/h, the depth is between 500 and 100m, the lifting speed is controlled within 2500m/h, the depth is between 100 and 20m, and the lifting speed is controlled within 1600 m/h.

(17) And when the tool string is 10m away from the wellhead, opening the anti-falling device flashboard, stopping lifting by power, pulling the tool string into the blowout-preventing pipe by manually carrying out back-pressing or hand-pressing on the cable, closing the anti-falling device flashboard, and checking the number of layers of the cable and the number of turns of the outermost cable. (checking the depth of lift to ensure that the cable and tool are all inside the lubricator, preventing the ram from cutting the cable)

(18) And informing the winch worker to slowly lower the cable, detecting the flashboard of the anti-falling device for 2-3 times, confirming that the tool string completely enters the blowout prevention pipe together with the winch worker, and closing the paraffin removal gate.

16. Emptying

17. Unloading blowout-preventing pipe

18. Disassembling tool

19. Fracturing construction

And performing fracturing construction according to a fracturing pump injection program after the multi-cluster perforation operation is finished.

20. The rest of each section

And (3) stopping the pump to measure the pressure drop for 30 minutes each time after the fracturing construction is finished, and then completing the multi-cluster perforation of the pumping bridge plug, drilling and milling the bridge plug and fracturing integrated combined construction of the other sections according to the steps of 4-18.

The fracturing sand adopted by the fracturing construction is a natural quartz sand performance index: the breaking rate is less than or equal to 14 percent under the pressure of 28 MPa. The fracturing fluid is active water, and clear water and 0.5 percent KCl can be selected. The liquid preparation requirements are as follows: and stirring circulation is carried out in the process of adding the KCl, so that the KCl is fully dissolved.

The construction process of fracturing construction is as follows:

(1) connecting and constructing pipelines, circulating a main pressure vehicle by using active water, returning circulating liquid to a large tank, and testing the pressure of the pipelines and a wellhead at 45 MPa.

(2) Pumping the first section of bridging and shooting combined tool to a preset perforation, lifting the perforating gun to a first cluster position after the bridging plug seat is sealed, and applying pressure to a shaft by 20 MPa.

(3) And performing perforation operation after the pressure test of the shaft is qualified.

(4) And (5) putting forward a perforating gun, performing the first-stage fracturing construction according to a pumping program, and injecting by using a light sleeve.

(5) And (4) performing the next section of bridge shooting operation after fracturing is finished (the subsequent construction is repeatedly performed according to the steps 2 to 4).

And (4) pumping and injecting program: (first stage simulation)

Post-press work

(1) And after the whole well construction is finished, open flow and liquid drainage are carried out, and open flow is controlled by an oil nozzle.

(2) When the pressure of a well head is more than 10MPa, a 5mm oil nozzle is adopted for open flow; when the pressure of the well head is 10-5MPa, an oil nozzle with the diameter of 8mm is adopted for open flow; when the pressure is 5-2MPa, a 12mm oil nozzle is adopted for open flow; and when the pressure is less than 2MPa, open blowing.

(3) And (3) monitoring requirements of blowout operation: the spraying liquid enters a metering tank for metering, and the spraying conditions including time, nozzle size, wellhead pressure, accumulated liquid amount, water quality expression, ash and sand discharging description and the like are observed and recorded every 2 hours.

(4) And after the pressure of the well head is zero, drilling and grinding a bridge plug and sand washing by a lower grinding and milling tool, and describing and recording the condition of the returned substances.

Drilling and grinding:

(1) assembling the drill bit short circuit and the drill bit to the tail end of the oil pipe:

drilling tool combination:2-7/8 TBG oil pipe and 2-7/8 TG are respectively provided with a 50MPa check valve, a change buckle joint and a screw drill (5 LZ95- 7L) + five-blade milling shoe

(2) The tubing assembly is run to the bottom until it lightly contacts the composite bridge plug.

(3) And lifting the pipe column to be 1.2-1.8 m away from the top end of the composite bridge plug.

(4) Maintaining the pumping speed at about 0.5m³More than min.

(5) The pump injection is started to drive the drill bit, and the rotating speed is about 100-125 revolutions per minute.

(6) The string is lowered slowly until the pump pressure increases or the deadweight decreases.

(7) And starting to drill and grind the bridge plug. The first few minutes will grind away the upper half of the center tube.

(8) Any increase in pressure while drilling is due to the composite bridge plug being drilled to balance.

(9) And lifting the pipe column to circulate to make the grinding material far away from the upper end of the bridge plug.

(10) And applying 1t of force to continuously drill and grind the composite bridge plug.

(11) After the upper part of the composite bridge plug is drilled and ground, the oil pipe string is lifted by 1.5m, and balance and circular grinding of the lower area are ensured.

(12) And continuing to drill and grind the composite bridge plug until the weight of the tubing string and the pump pressure are recovered.

(13) Keeping the displacement circulating for 1.5-2 volumes, observing the outlet without impurities continuously, and stopping the pump.

(14) Pushing the lower half part of the composite bridge plug to the bottom of the well or the upper part of the next bridge plug, if the lower half part of the composite bridge plug meets a sand clamp in the pushing process, pulling out a drilling and grinding pipe column, punching the sand from the lower sand pipe column, and pushing the lower half part of the composite bridge plug to the bottom of the well or the upper part of the next bridge plug.

(15) For drilling and grinding of a plurality of bridge plugs, the drilling and grinding are continued from step 7 before the pump is stopped.

(16) Drilling and grinding the lower portion of the first bridge plug will increase the milling time somewhat.

Note that: during the grinding process, the change of the pump pressure is noticed, when the rubber barrel part is ground, the pump pressure is possibly suddenly increased, at the moment, the pump is stopped, but the hanging weight and the slight movable pipe column are kept, and the grinding is continued after the pressure is recovered to be normal.

Hydraulic jetting or small-sized fracturing and seam making are carried out upwards in the lower horizontal well, a drainage channel is formed, the drainage channel flows to the lower bottom plate 3 branch horizontal well (the horizontal section of the first horizontal well) under the action of the gravity of water, and then an oil pipe is lowered into the vertical well (the vertical section of the first horizontal well) to the lower boundary of the coal bed methane for drainage, depressurization and gas production.

The utility model provides a coal bed gas F type horizontal well system not only is applicable to the exploitation of coal bed gas, also is applicable to other geological deposits that use drainage depressurization method to exploit simultaneously.

The horizontal branch well is constructed in the upper bottom plate and the lower bottom plate of the target coal bed, as the upper top plate and the lower bottom plate of the low-order coal bed and the structural coal bed are mostly sand shale or metamorphic rock, the stability is better relative to the coal bed, and various mud systems can be used in the drilling process without polluting the target layer; the horizontal well drilling tool can effectively avoid the complex conditions of well leakage, coal bed collapse and the like of a well bore of the horizontal well in the well drilling process, can also use more advanced near-drill bits and rotary steering instruments in China to accelerate the construction progress, and promotes the development of domestic directional instruments and levels.

The natural filtering barrier for low-rank coal ventilation is formed by fracturing and seam making of the upper top plate in a large scale, so that the problem that a low-rank coal bed methane seepage channel is easy to block is solved; through lower plate hydraulic jet or small-size fracturing joint-making, for the permeable to water depressurization creation condition of low order coal, can prevent moreover that the buggy from excessively adopting, through the drainage depressurization gas production of vertical shaft realize the high-efficient exploitation of low order coal bed gas. The utility model discloses a separation of drainage and gas production has improved row and has adopted efficiency.

Finally, it should be noted that: the above embodiments are only used to illustrate the technical solution of the present invention, and not to limit it; although the present invention has been described in detail with reference to the foregoing embodiments, it should be understood by those skilled in the art that: the technical solutions described in the foregoing embodiments may still be modified, or some technical features may be equivalently replaced; such modifications and substitutions do not depart from the spirit and scope of the present invention in its corresponding aspects.

Claims (10)

1. The coal bed gas horizontal well system is characterized by comprising a horizontal well group, wherein the horizontal well group comprises a first horizontal well track and a second horizontal well track, the first horizontal well track is positioned on a lower bottom plate of a coal bed with a relatively stable geological structure, and the second horizontal well track is positioned on an upper top plate of the coal bed with a relatively stable geological structure; the first horizontal well track is in an inverted L shape, and the first horizontal well track is connected with the second horizontal well track to form an inverted F-shaped horizontal well group.

2. The coalbed methane horizontal well system of claim 1, wherein the first horizontal well trajectory comprises a vertical section, a bent section and a horizontal section, the vertical section penetrating through the upper coal seam roof, the coal seam and the lower coal seam floor; the horizontal section is arranged on a lower bottom plate of the coal seam and is parallel to the coal seam, and the distance between the horizontal section and the lower boundary of the coal seam is 0.2-2.0 m; two ends of the bending section are respectively connected with the vertical section and the horizontal section.

3. The coalbed methane horizontal well system of claim 2, wherein the vertical section is provided with a surface casing, the bent section and the horizontal section to the bottom of the well is provided with a production casing to form a first horizontal well.

4. The coalbed methane horizontal well system of claim 2, wherein the vertical section and the bent section are provided with a cement layer to seal the first horizontal well.

5. The coalbed methane horizontal well system as recited in claim 2, wherein the first horizontal well is connected with the coal seam through at least one first perforation, and the first horizontal well can hydraulically jet or small-sized fracture and seam the coal seam through the first perforation to form a drainage and exhaust channel.

6. The coalbed methane horizontal well system of claim 4, wherein the lower boundary of the coal seam is provided with tubing for drainage, depressurization and gas production.

7. The coalbed methane horizontal well system of claim 1, wherein the second horizontal well trajectory comprises a windowed sidetrack and a horizontal section, the windowed sidetrack having production casing disposed downhole to form a second horizontal well.

8. The coal bed gas horizontal well system as claimed in claim 7, wherein the horizontal section of the second horizontal well is parallel to the coal bed, and the distance between the horizontal section of the second horizontal well and the upper boundary of the coal bed is 0.2-2.0 m.

9. The coalbed methane horizontal well system of claim 7, wherein the second horizontal well is connected with the coal seam through at least one second perforation, and the second horizontal well can perform scale staged fracturing or drag fracturing on the coal seam through the second perforation to form a fracture in the coal seam.

10. The coalbed methane horizontal well system of claim 9, wherein propped sand is disposed within the fractures of the coal seam to form a passage for low-rank coal bed methane and to increase the seepage passage for coal bed methane.

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