CN212898453U

CN212898453U - Leading energizer fracturing unit of natural gas

Info

Publication number: CN212898453U
Application number: CN202021424599.9U
Authority: CN
Inventors: 石刚; 张健; 薛旭周; 段超; 周聪
Original assignee: Jereh Energy Services Corp
Current assignee: Jereh Energy Services Corp
Priority date: 2020-07-17
Filing date: 2020-07-17
Publication date: 2021-04-06
Anticipated expiration: 2030-07-17

Abstract

The utility model discloses a leading energization fracturing unit of natural gas, including natural gas source, compressor, one-level instrument well, second grade instrument well, fracturing truck, fluid reservoir and fracturing well. Has the advantages that: natural gas is used as energizing gas, and the natural gas can be dissolved in crude oil to expand the crude oil and reduce the viscosity; miscible phase flooding can be formed in a reservoir, the interfacial tension is reduced, the number of capillary tubes is increased, and the saturation of residual oil is greatly reduced, so that the recovery rate of crude oil is improved; the natural gas has wide source, low price, convenience, rapidness and optimal benefit; adopt one-level tool well and second grade tool well to carry out the pressure boost to the natural gas, increase tool well single gas storage ability, the pressure boost effect is not limited by compressor power, and the single gas injection volume is big, reduces the dependence to the compressor, and accessible multiple supercharging further increases pressure simultaneously satisfies the requirement of big discharge capacity, high pressure.

Description

Leading energizer fracturing unit of natural gas

Technical Field

The utility model relates to a fracturing technical field, concretely relates to leading energizer fracturing unit of natural gas.

Background

The gas preposed energizing fracturing technology is characterized in that a certain amount of gas is injected into a perforation section after single-stage perforation and before staged fracturing on the basis of conventional water-based fracturing fluid, the elastic energy of the gas and the characteristic of miscible-phase flooding formed by the gas and crude oil are utilized to supplement energy for a stratum and improve the recovery ratio of compact oil, and meanwhile, the gas does not damage an oil layer basically, so that the flow-back efficiency of the fracturing fluid can be improved, the damage of the fracturing fluid to the oil layer is reduced, and the aims of improving the seepage capability of cracks and increasing the productivity of an oil well are fulfilled. At present, CO is mainly adopted for gas preposed energizing fracturing₂Or N₂As the energizing gas, although the fracturing effect can be improved, CO is used₂Or N₂Can generate strong corrosion to surface equipment, pipelines and mineshafts, requires special equipment for production, and has high gas injection cost; and the waste is useless after the extraction, and has certain pollution to the environment. And the gas injection is limited by the power of a compressor or a high-pressure pump, so that the single gas injection has low energy storage, low gas injection pressure and small discharge capacity.

SUMMERY OF THE UTILITY MODEL

The utility model aims to overcome the defects of the prior art and provide a natural gas preposed energizing fracturing device, which adopts natural gas as energizing gas, and the natural gas can be dissolved in crude oil to expand the crude oil and reduce the viscosity; miscible phase flooding can be formed in a reservoir, the interfacial tension is reduced, the number of capillary tubes is increased, and the saturation of residual oil is greatly reduced, so that the recovery rate of crude oil is improved; the natural gas has wide source, low price, convenience, rapidness and optimal benefit; adopt one-level tool well and second grade tool well to carry out the pressure boost to the natural gas, increase tool well single gas storage ability, the pressure boost effect is not limited by compressor power, and the single gas injection volume is big, reduces the dependence to the compressor, and accessible multiple supercharging further increases pressure simultaneously satisfies the requirement of big discharge capacity, high pressure.

The purpose of the utility model is achieved through the following technical measures: the utility model provides a leading fracturing unit that energizates of natural gas, includes natural gas source, compressor, one-level tool well, second grade tool well, fracturing truck, fluid reservoir and fracturing well, one-level tool well and second grade tool well all are equipped with gaseous phase import, gaseous phase export, liquid phase import and liquid phase export, natural gas source and compressor are connected in proper order, the compressor still respectively with the gaseous phase access connection of one-level tool well and second grade tool well, the gaseous phase export of one-level tool well and second grade tool well all is connected with the fracturing well, the fracturing truck respectively with the liquid phase access connection of one-level tool well and second grade tool well, the liquid phase export of one-level tool well and second grade tool well all is connected with the fluid reservoir, the second grade tool well is more than 1, and is a plurality of the second grade tool well is parallelly connected.

Further, one-level tool well and second grade tool well all include sleeve pipe, oil pipe and well head, the well head is equipped with gaseous phase import, gaseous phase export, liquid phase import and liquid phase export, gaseous phase import and gaseous phase export are connected with sheathed tube one end respectively, the sheathed tube other end stretches into the shaft bottom and sealed the setting, liquid phase import and liquid phase export are connected with oil pipe's one end respectively, oil pipe's the other end stretches into in the sleeve pipe and communicates with the sleeve pipe.

Further, the fracturing truck is also connected with a liquid tank.

Further, the natural gas source is a CNG tank truck or a natural gas conveying pipeline.

Furthermore, the gas-phase inlet, the gas-phase outlet, the liquid-phase inlet and the liquid-phase outlet of the first-stage tool well and the second-stage tool well and the inlet ends of the fracturing wells are respectively provided with a safety valve.

Further, the safety valves can be remotely controlled.

Compared with the prior art, the beneficial effects of the utility model are that: natural gas is used as energizing gas, and the natural gas can be dissolved in crude oil to expand the crude oil and reduce the viscosity; miscible phase flooding can be formed in a reservoir, the interfacial tension is reduced, the number of capillary tubes is increased, and the saturation of residual oil is greatly reduced, so that the recovery rate of crude oil is improved; the natural gas has wide source, low price, convenience, rapidness and optimal benefit; adopt one-level tool well and second grade tool well to carry out the pressure boost to the natural gas, increase tool well single gas storage ability, the pressure boost effect is not limited by compressor power, and the single gas injection volume is big, reduces the dependence to the compressor, and accessible multiple supercharging further increases pressure simultaneously satisfies the requirement of big discharge capacity, high pressure.

The present invention will be described in detail with reference to the accompanying drawings and specific embodiments.

Drawings

FIG. 1 is a schematic diagram of a natural gas pre-energized fracturing unit with 1 secondary tool well.

Fig. 2 is a schematic diagram of a natural gas pre-energized fracturing device with 2 secondary tool wells.

The system comprises a CNG tank truck, a compressor, a first-stage tool well, a second-stage tool well, a fracturing truck, a tank, a fracturing well, a first safety valve, a second safety valve, a third safety valve, a fourth safety valve, a sixth safety valve, a fifth safety valve, a seventh safety valve, an eighth safety valve, a ninth safety valve, a first second-stage tool well, a second safety valve, a third safety valve, a fourth safety valve, a sixth safety valve, a fifth safety valve, a seventh safety valve, a sixth safety valve, a ninth safety valve, a first second-stage tool well, a second.

Detailed Description

As shown in fig. 1 to 2, the natural gas preposed energizing fracturing device comprises a natural gas source, a compressor 2, a first-stage tool well 3, a second-stage tool well 4, a fracturing truck 5, a liquid tank 6 and a fracturing well 7, wherein the first-stage tool well 3 and the second-stage tool well 4 are respectively provided with a gas phase inlet, a gas phase outlet, a liquid phase inlet and a liquid phase outlet, and the natural gas source is a CNG tank truck 1 or a natural gas conveying pipeline. The natural gas source is connected with the compressor 2 in sequence, the compressor 2 is further connected with gas phase inlets of the first-stage tool well 3 and the second-stage tool well 4 respectively, and specifically, the compressor 2 is used for injecting natural gas into the first-stage tool well 3 and the second-stage tool well 4. The gaseous phase export of one-level instrument well 3 and second grade instrument well 4 all is connected with fracturing well 7, and is specific, one-level instrument well 3 and second grade instrument well 4 are used for injecting the natural gas into fracturing well 7. Fracturing unit 5 is connected with the liquid phase inlet of one-level tool well 3 and second grade tool well 4 respectively, the liquid phase export of one-level tool well 3 and second grade tool well 4 all is connected with fluid reservoir 6, second grade tool well 4 is more than 1, and is a plurality of second grade tool well 4 connects in parallel. Adopt one-level tool well 3 and second grade tool well 4 to carry out the pressure boost to the natural gas, increase tool well single gas storage ability, the pressure boost effect is not limited by compressor power, and single gas injection volume is big, reduces the dependency to compressor 2.

The one-level tool well 3 and the second-level tool well 4 both comprise a casing, an oil pipe and a well mouth, the well mouth is provided with a gas phase inlet, a gas phase outlet, a liquid phase inlet and a liquid phase outlet, the gas phase inlet and the gas phase outlet are respectively connected with one end of the casing, the other end of the casing extends into the well bottom and is hermetically arranged, the liquid phase inlet and the liquid phase outlet are respectively connected with one end of the oil pipe, and the other end of the oil pipe extends into the casing and is communicated with the casing. Specifically, the pipe diameter, the wall thickness and the material of the casing pipe and the oil pipe of the first-stage tool well 3 and the second-stage tool well 4 and the well depth can be set according to the actual fracturing gas injection requirement. The natural gas can enter the casing from the gas phase inlet and discharge the fracturing fluid in the casing into the liquid tank through the oil pipe and the liquid phase outlet. The fracturing fluid can enter the oil pipe from the liquid phase inlet and can enter the casing pipe from the oil pipe to discharge natural gas in the casing pipe into the fracturing well 7 from the gas phase outlet. And the fracturing fluid can enter the oil pipe of the primary tool well 3 from the liquid phase inlet of the primary tool well 3 and enter the casing pipe from the oil pipe, and natural gas in the casing pipe is discharged into the casing pipe of the secondary tool well 4 from the gas phase outlet of the primary tool well 3 through the gas phase outlet of the secondary tool well 4 to pressurize the secondary tool well 4.

The fracturing truck 5 is also connected with a liquid tank 6. The liquid tank 6 can supply liquid for the fracturing truck 5, so that the fracturing liquid can be recycled.

And safety valves are arranged at the gas-phase inlet, the gas-phase outlet, the liquid-phase inlet and the liquid-phase outlet of the first-stage tool well 3 and the second-stage tool well 4 and at the inlet ends of the fracturing wells 7. Specifically, a first safety valve 8 is arranged between the compressor 2 and a gas-phase inlet of the primary tool well 3, a second safety valve 9 is arranged between the compressor 2 and a gas-phase inlet of the secondary tool well 4, a third safety valve 10 is arranged between a gas-phase outlet of the primary tool well 3 and the fracturing well 7, a fourth safety valve 11 is arranged between a gas-phase outlet of the secondary tool well 4 and the fracturing well 7, a fifth safety valve 13 is arranged between the fracturing truck 5 and a liquid-phase inlet of the primary tool well 3, a sixth safety valve 12 is arranged between the fracturing truck 5 and a liquid-phase inlet of the secondary tool well 4, a seventh safety valve 14 is arranged between a liquid-phase outlet of the primary tool well 3 and the liquid tank 6, an eighth safety valve 15 is arranged between a liquid-phase outlet of the secondary tool well 4 and the liquid tank 6, a ninth safety valve 16 is arranged at an inlet end of the fracturing well 7, and when a plurality of

secondary tool wells

4, 4 safety valves are added for each additional secondary tool well 4.

The safety valves can be remotely controlled. All opening and closing of relief valve all can adopt remote control system to carry out remote control, avoid on-the-spot manual operation, use manpower sparingly, reduce manual operation's safe risk simultaneously, factor of safety is high.

When second grade tool well 4 is a plurality of, first-level tool well 3 carries out the gas injection pressure boost to a plurality of second grade tool well 4 respectively after, the natural gas source injects the natural gas into first-level tool well 3 again through compressor 2, accomplishes 4 single pressure boosts of second grade tool well. Specifically, one-level tool well 3 injects gas to a plurality of second grade tool wells 4 in proper order, waits all second grade tool wells 4 after all pressure boost, and the natural gas source injects the natural gas into one-level tool well 3 again through compressor 2, accomplishes the single pressure boost of all second grade tool wells 4. Specifically, the number of pressurization times of the secondary tool well 4 can be selected according to the gas injection pressure requirement of the fracturing well 7.

When there are a plurality of secondary tool wells 4, one of the secondary tool wells 4 may pressurize any one of the secondary tool wells 4 other than that. Specifically, the need to pressurize other secondary tool wells 4 in addition to a single secondary tool well 4 may be determined based on the pressure capacity of the secondary tool well 4 and the gas injection pressure requirements of the frac well 7.

Example 1

As shown in fig. 1, this embodiment is a natural gas pre-energized fracturing unit with 1 secondary tool well 4.

The utility model provides a leading energization fracturing unit of natural gas, includes natural gas source, compressor 2, one-level tool well 3, second grade tool well 4, fracturing truck 5, fluid reservoir 6 and fracturing well 7, one-level tool well 3 and second grade tool well 4 all are equipped with gaseous phase import, gaseous phase export, liquid phase import and liquid phase export, natural gas source is CNG tank car 1. The natural gas source is sequentially connected with the compressor 2, the compressor 2 is connected with gas phase inlets of the first-stage tool well 3 and the second-stage tool well 4 through a first safety valve 8 and a second safety valve 9 respectively, gas phase outlets of the first-stage tool well 3 and the second-stage tool well 4 are connected with the fracturing well 7 through a third safety valve 10 and a fourth safety valve 11 respectively, and a ninth safety valve 16 is further arranged between the third safety valve 10 and the fracturing well 7 and between the fourth safety valve 11 and the fracturing well 7. The fracturing truck 5 is connected with liquid phase inlets of the first-stage tool well 3 and the second-stage tool well 4 through a fifth safety valve 13 and a sixth safety valve 12 respectively, liquid phase outlets of the first-stage tool well 3 and the second-stage tool well 4 are connected with the liquid tank 6 through a seventh safety valve 14 and an eighth safety valve 15 respectively, and the fracturing truck 5 is further connected with the liquid tank 6.

The one-level tool well 3 and the second-level tool well 4 both comprise a casing, an oil pipe and a well mouth, the well mouth is provided with a gas phase inlet, a gas phase outlet, a liquid phase inlet and a liquid phase outlet, the gas phase inlet and the gas phase outlet are respectively connected with one end of the casing, the other end of the casing extends into the well bottom and is hermetically arranged, the liquid phase inlet and the liquid phase outlet are respectively connected with one end of the oil pipe, and the other end of the oil pipe extends into the casing and is communicated with the casing.

The first safety valve 8, the second safety valve 9, the third safety valve 10, the fourth safety valve 11, the fifth safety valve 13, the sixth safety valve 12, the seventh safety valve 14, the eighth safety valve 15 and the ninth safety valve 16 can be controlled remotely.

The working principle is as follows:

gas injection from the primary tool well 3 and the secondary tool well 4: and (3) closing the third safety valve 10, the fourth safety valve 11, the fifth safety valve 13, the sixth safety valve 12 and the ninth safety valve 16, opening the first safety valve 8, the second safety valve 9, the seventh safety valve 14 and the eighth safety valve 15, compressing natural gas in the CNG tank truck 1 by the compressor 2, then entering the primary tool well 3 through the first safety valve 8, discharging fracturing fluid in the primary tool well 3 into the liquid tank 6 through the seventh safety valve 14, and injecting gas into the primary tool well 3. Meanwhile, the compressed natural gas enters the secondary tool well 4 through the second safety valve 9 and discharges fracturing fluid in the secondary tool well 4 into the fluid tank 6 through the eighth safety valve 15, and the secondary tool well 4 injects the gas.

And (4) pressurizing the secondary tool well: closing a first safety valve 8, a second safety valve 9, a sixth safety valve 12, a seventh safety valve 14, an eighth safety valve 15 and a ninth safety valve 16, opening a fifth safety valve 13, a third safety valve 10 and a fourth safety valve 11, injecting fracturing fluid into the primary tool well 3 by the fracturing truck 5, discharging natural gas in the primary tool well 3 into the secondary tool well 4 by the fracturing fluid through the third safety valve 10 and the fourth safety valve 11, pressurizing the natural gas in the secondary tool well 4 to finish single pressurization of the secondary tool well 4, then closing the third safety valve 10, the fourth safety valve 11 and the fifth safety valve 13, opening the seventh safety valve 14, feeding the fracturing fluid in the primary tool well 3 into the fluid tank 6 through the seventh safety valve 14, releasing pressure in the primary tool well 3 by the first safety valve 8 after the pressure of the first safety valve 8 is released, feeding the natural gas into the primary tool well 3 through the first safety valve 8 after the natural gas is compressed by the pressure releasing compressor 2 and discharging the fracturing fluid in the primary tool well 3 to the seventh safety valve 6 through the seventh safety valve 14, the primary tool well 3 is reinjected.

Gas injection of the fracturing well 7: and (3) closing the first safety valve 8, the second safety valve 9, the fourth safety valve 11, the sixth safety valve 12, the seventh safety valve 14 and the eighth safety valve 15, opening the fifth safety valve 13, the third safety valve 10 and the ninth safety valve 16, injecting the fracturing fluid into the primary tool well 3 through the fifth safety valve 13 by the fracturing truck 5, discharging the natural gas in the primary tool well 3 into the fracturing well 7 through the third safety valve 10 and the ninth safety valve 16, and completing gas injection of the primary tool well 3. And then closing the fifth safety valve 13 and the third safety valve 10, opening the sixth safety valve 12 and the fourth safety valve 11, injecting the fracturing fluid into the secondary tool well 4 through the sixth safety valve 12 by the fracturing truck 5, discharging the natural gas in the secondary tool well 4 into the fracturing well 7 through the fourth safety valve 11 and the ninth safety valve 16, completing gas injection of the secondary tool well 4, and realizing single gas injection of the fracturing well 7.

Example 2

Example 2 is a natural gas pre-energized fracturing apparatus with 2 secondary tool wells 4. Different from the embodiment 1, the natural gas pre-energized fracturing device also comprises a tenth safety valve 19, an eleventh safety valve 20, a twelfth safety valve 21 and a thirteenth safety valve 22, the secondary tool well 4 comprises a first secondary tool well 17 and a second secondary tool well 18, the first secondary tool well 17 and the second secondary tool well 18 being connected in parallel, the compressor 2 is connected to the gas phase inlet of the first secondary tool well 17 via a second safety valve 9, the compressor 2 is connected to the gas phase inlet of the second secondary tool well 18 via a tenth safety valve 19, the gas phase outlet of the first secondary tool well 17 is connected with the fracturing well 7 through a fourth safety valve 11, the gas phase outlet of the second secondary tool well 18 is connected with the fracturing well 7 through an eleventh safety valve 20, and a ninth safety valve 16 is arranged between the third safety valve 10, the fourth safety valve 11 and the eleventh safety valve 20 and the fracturing well 7. The fracturing truck 5 is connected with a liquid phase inlet of a first secondary tool well 17 through a sixth safety valve 12, the fracturing truck 5 is connected with a liquid phase inlet of a second secondary tool well 18 through a twelfth safety valve 21, a liquid phase outlet of the first secondary tool well 17 is connected with the liquid tank 6 through an eighth safety valve 15, and a liquid phase outlet of the second secondary tool well 18 is connected with the liquid tank 6 through a thirteenth safety valve 22.

The first relief valve 8, the second relief valve 9, the third relief valve 10, the fourth relief valve 11, the fifth relief valve 13, the sixth relief valve 12, the seventh relief valve 14, the eighth relief valve 15, the ninth relief valve 16, the tenth relief valve 19, the eleventh relief valve 20, the twelfth relief valve 21 and the thirteenth relief valve 22 can all be remotely controlled.

The working principle is as follows:

gas injection from the primary tool well 3 and the secondary tool well 4: and (3) closing the third safety valve 10, the fourth safety valve 11, the fifth safety valve 13, the sixth safety valve 12, the ninth safety valve 16, the eleventh safety valve 20 and the twelfth safety valve 21, opening the first safety valve 8, the second safety valve 9, the seventh safety valve 14, the eighth safety valve 15, the tenth safety valve 19 and the thirteenth safety valve 22, compressing natural gas in the CNG tank truck 1 through the compressor 2, entering the primary tool well 3 through the first safety valve 8, discharging fracturing fluid in the primary tool well 3 into the liquid tank 6 through the seventh safety valve 14, and injecting gas into the primary tool well 3. Meanwhile, the compressed natural gas enters the first secondary tool well 17 through the second safety valve 9, fracturing fluid in the first secondary tool well 17 is discharged into the fluid tank 6 through the eighth safety valve 15, and gas is injected into the first secondary tool well 17. Meanwhile, the compressed natural gas enters the second-stage tool well 18 through the tenth safety valve 19 and discharges fracturing fluid in the second-stage tool well 18 into the fluid tank 6 through the thirteenth safety valve 22, and the second-stage tool well 18 is injected with gas.

And (3) pressurizing the secondary tool well: closing a first safety valve 8, a second safety valve 9, a sixth safety valve 12, a seventh safety valve 14, an eighth safety valve 15, a ninth safety valve 16, a tenth safety valve 19, an eleventh safety valve 20, a twelfth safety valve 21 and a thirteenth safety valve 22, opening a fifth safety valve 13, a third safety valve 10 and a fourth safety valve 11, injecting fracturing fluid into the primary tool well 3 by a fracturing truck 5, discharging natural gas in the primary tool well 3 into a first secondary tool well 17 through the fracturing fluid via the third safety valve 10 and the fourth safety valve 11, pressurizing natural gas in the first secondary tool well 17 to finish single pressurization of the first secondary tool well 17, then closing the third safety valve 10, the fourth safety valve 11 and the fifth safety valve 13, opening the seventh safety valve 14, introducing the fracturing fluid in the primary tool well 3 into a fluid tank 6 through the seventh safety valve 14, depressurizing the primary tool well 3, opening the first safety valve 8 after depressurization, the natural gas is compressed by the compressor 2 and then enters the first-stage tool well 3 through the first safety valve 8, the fracturing fluid in the first-stage tool well 3 is discharged to the fluid tank 6 through the seventh safety valve 14, and the first-stage tool well 3 is injected again. Closing a first safety valve 8, a second safety valve 9, a fourth safety valve 11, a sixth safety valve 12, a seventh safety valve 14, an eighth safety valve 15, a ninth safety valve 16, a tenth safety valve 19, a twelfth safety valve 21 and a thirteenth safety valve 22, opening a fifth safety valve 13, a third safety valve 10 and an eleventh safety valve 20, injecting fracturing fluid into the primary tool well 3 by a fracturing truck 5, discharging natural gas in the primary tool well 3 into a second secondary tool well 18 by the fracturing fluid through the third safety valve 10 and the eleventh safety valve 20, pressurizing the natural gas in the second secondary tool well 18 to finish single pressurization of the second secondary tool well 18, then closing the third safety valve 10, the eleventh safety valve 20 and the fifth safety valve 13, opening the seventh safety valve 14, feeding the fracturing fluid in the primary tool well 3 into a fluid tank 6 through the seventh safety valve 14, depressurizing the primary tool well 3, and after pressure relief, the first safety valve 8 is opened, natural gas is compressed by the compressor 2 and then enters the first-stage tool well 3 through the first safety valve 8, fracturing fluid in the first-stage tool well 3 is discharged to the fluid tank 6 through the seventh safety valve 14, the first-stage tool well 3 injects gas again, and the single pressurization process of the first second-stage tool well 17 and the second-stage tool well 18 is realized.

Gas injection of a fracturing well: and (3) closing the first safety valve 8, the second safety valve 9, the fourth safety valve 11, the sixth safety valve 12, the seventh safety valve 14, the eighth safety valve 15, the tenth safety valve 19, the eleventh safety valve 20, the twelfth safety valve 21 and the thirteenth safety valve 22, opening the fifth safety valve 13, the third safety valve 10 and the ninth safety valve 16, injecting fracturing fluid into the primary tool well 3 through the fifth safety valve 13 by the fracturing truck 5, discharging natural gas in the primary tool well 3 into the fracturing well 7 through the third safety valve 10 and the ninth safety valve 16, and completing gas injection of the primary tool well 3. And then closing the fifth safety valve 13 and the third safety valve 10, opening the sixth safety valve 12 and the fourth safety valve 11, injecting the fracturing fluid into the first secondary tool well 17 through the sixth safety valve 12 by the fracturing truck 5, and discharging the natural gas in the first secondary tool well 17 into the fracturing well 7 through the fourth safety valve 11 and the ninth safety valve 16 to complete gas injection of the first secondary tool well 17. And then closing the fourth safety valve 11 and the sixth safety valve 12, opening the twelfth safety valve 21 and the eleventh safety valve 20, injecting the fracturing fluid into the second-stage tool well 18 through the twelfth safety valve 21 by the fracturing truck 5, discharging the natural gas in the second-stage tool well 18 into the fracturing well 7 through the eleventh safety valve 20 and the ninth safety valve 16, and completing the gas injection of the second-stage tool well 18. A single gas injection of the fracture well 7 is achieved.

In the actual operation process, in the process of pressurizing the secondary tool well 4, after the first secondary tool well 17 and the second secondary tool well 18 are pressurized, according to the pressure bearing capacity of the first secondary tool well 17 and/or the second secondary tool well 18 and the gas injection pressure requirement of the fracturing well 7, the first safety valve 8, the second safety valve 9, the third safety valve 10, the fifth safety valve 13, the seventh safety valve 14, the eighth safety valve 15, the ninth safety valve 16, the tenth safety valve 19, the twelfth safety valve 21 and the thirteenth safety valve 22 are closed, the sixth safety valve 12, the fourth safety valve 11 and the eleventh safety valve 20 are opened, so that the fracturing fluid discharges the pressurized natural gas in the first secondary tool well 17 into the second secondary tool well 18 for re-pressurization, or the first safety valve 8, the second safety valve 9, the third safety valve 10, the fifth safety valve 13, the sixth safety valve 12, And the seventh safety valve 14, the eighth safety valve 15, the ninth safety valve 16, the tenth safety valve 19 and the thirteenth safety valve 22 are opened, and the twelfth safety valve 21, the fourth safety valve 11 and the eleventh safety valve 20 are opened, so that the fracturing fluid discharges the pressurized natural gas in the second-stage tool well 18 into the first second-stage tool well 17 for re-pressurization.

It will be understood by those skilled in the art that the present invention is not limited to the above embodiments, and that the foregoing embodiments and descriptions are provided only to illustrate the principles of the present invention without departing from the spirit and scope of the present invention. The scope of the invention is defined by the appended claims and equivalents thereof.

Claims

1. The utility model provides a leading energization fracturing unit of natural gas which characterized in that: including natural gas source, compressor, one-level tool well, second grade tool well, fracturing truck, fluid reservoir and fracturing well, one-level tool well and second grade tool well all are equipped with gaseous phase import, gaseous phase export, liquid phase import and liquid phase export, natural gas source and compressor connect gradually, the compressor still respectively with the gaseous phase access connection of one-level tool well and second grade tool well, the gaseous phase export of one-level tool well and second grade tool well all is connected with the fracturing well, the fracturing truck respectively with the liquid phase access connection of one-level tool well and second grade tool well, the liquid phase export of one-level tool well and second grade tool well all is connected with the fluid reservoir, the second grade tool well is more than 1, and is a plurality of the second grade tool well is parallelly connected.

2. The natural gas pre-energized fracturing device of claim 1, wherein: the one-level tool well and the second-level tool well comprise a casing, an oil pipe and a well mouth, the well mouth is provided with a gas phase inlet, a gas phase outlet, a liquid phase inlet and a liquid phase outlet, the gas phase inlet and the gas phase outlet are respectively connected with one end of the casing, the other end of the casing extends into the well bottom and is hermetically arranged, the liquid phase inlet and the liquid phase outlet are respectively connected with one end of the oil pipe, and the other end of the oil pipe extends into the casing and is communicated with the casing.

3. The natural gas pre-energized fracturing device of claim 1, wherein: the fracturing truck is also connected with the liquid tank.

4. The natural gas pre-energized fracturing device of claim 1, wherein: the natural gas source is a CNG tank car or a natural gas conveying pipeline.

5. The natural gas pre-energized fracturing device of claim 1, wherein: and safety valves are arranged at the gas-phase inlet, the gas-phase outlet, the liquid-phase inlet, the liquid-phase outlet and the inlet ends of the fracturing wells of the first-stage tool well and the second-stage tool well.

6. The natural gas pre-energized fracturing device of claim 5, wherein: the safety valves can be remotely controlled.