CN113323649B - Integrated flow-collecting bridge type testing, adjusting, inspecting, sealing and injecting system and using method thereof - Google Patents

Abstract

The invention relates to an integrated flow-collecting bridge type measurement, regulation, inspection, sealing and injection system and a using method thereof, which are applied to oilfield separate-layer water injection. The device comprises a water distributor and an underground measuring and adjusting instrument, wherein the water distributor is provided with a bridge type passage, a water distribution passage, a pressure measuring passage and a linked switch; the linked switch simultaneously controls the water distribution channel and the pressure measuring channel; the underground measuring and adjusting instrument is provided with three packing parts, and a water distribution channel and a pressure measuring channel of the water distributor are respectively positioned between the two packing parts; the underground testing and adjusting instrument is provided with an inner flow channel, and an outlet of the inner flow channel is communicated with a water distribution channel of the water distributor; the underground measuring and adjusting instrument is also provided with an external pressure sensor, an internal flow testing unit and an external flow testing unit. The using method comprises the following steps: setting three sealing elements, adjusting the injection amount, checking the sealing and measuring the pressure. The underground testing and adjusting instrument can complete all testing and adjusting operations by one-time descending, and the operation timeliness is high; the flow-collecting type test is realized, the test precision is high, and the lower limit is low.

Description

Integrated flow-collecting bridge type testing, adjusting, inspecting, sealing and injecting system and using method thereof

Technical Field

The invention relates to the technical field of layered water injection in oil field development of the petroleum industry, in particular to an integrated flow-collecting bridge type testing, adjusting, sealing and injecting system and a using method thereof.

Background

In the process of oil field development, separated layer water injection is one of the most important technologies for improving the oil field recovery efficiency. Through many years of attack and popularization, the current measurement and regulation integrated stratified water injection technology is widely applied to various domestic oil fields. The technology is divided into two parts of a downhole separate injection pipe column and a measuring and adjusting system. The underground separate injection pipe column comprises a separate layer packer and an adjustable water distributor. The testing and adjusting system comprises a surface controller, a cable and a downhole testing and adjusting instrument. The technology utilizes an underground measuring and adjusting instrument to adjust the water nozzle of the adjustable water distributor and simultaneously test the water injection amount. Compared with the prior art, the method has the advantages of simple process operation and quick time effect. If the layered packer needs to be tested or a certain injection layer needs to be tested, another set of instrument needs to be put in for testing, and the operation aging still needs to be improved.

In order to achieve the purpose, the Chinese patent 'bridge type measuring, adjusting, seal testing and pressure testing integrated high-efficiency water distributor', patent application number 201910485084.5, application date 2019.06.05, discloses a water distributor capable of being matched with an instrument to completely complete measuring, adjusting, seal testing and pressure testing after one-time well descending. The pressure measuring valve and the injection distributing valve of the water distributor disclosed use a one-way valve structure with a spring for jacking, the reliability of the structure is not high, and the sealing capability of the structure can be influenced by scaling after the structure works for a period of time in a well.

Chinese patent application No. 201510973113.4, application date 2015.12.22, discloses a measuring and regulating instrument with a double-packing-cup sealing mechanism. Compared with other measuring and regulating instruments, the measuring and regulating instrument can realize flow concentration test, lower limit of flow test is reduced, and test precision is improved. The sealing leather cup can only realize one-way sealing, namely, the sealing is realized by the pressure above the leather cup. The instrument does not have the functions of packer seal checking and pressure measurement aiming at a certain layer. According to the technical scheme disclosed in the application, only the rotating mechanism at the bottom and the positioning mechanism in the middle are arranged on the regulator, and the anti-reversal mechanism is not arranged on the regulator, so that the regulator does not have the function of regulating the flow of the water distributor. Although the application can perform the current collection test, the technical scheme of the current collection structure is not disclosed in the specification and the attached drawings.

Disclosure of Invention

In order to solve the technical problems, the invention provides an integrated flow-collecting bridge type measuring, adjusting, sealing, inspecting and injecting system and a using method thereof.

In order to realize the purpose, the invention adopts the following technical scheme:

the integrated flow-collecting bridge type test-adjustment, seal-inspection and injection-injection system comprises a water distributor and an underground test-adjustment instrument, wherein the water distributor is provided with a bridge type channel, a water distribution channel, a pressure measurement channel and a linked switch; the linked switch controls the water distribution channel and the pressure measuring channel at the same time, so that the water distribution channel and the pressure measuring channel are always in an on-off or full-off state; the linkage switch is driven by a circumferential positioning mechanism of the underground measuring and adjusting instrument; the periphery of the underground testing and adjusting instrument is provided with three packing parts which seal and separate an annular space between the water distributor and the underground testing and adjusting instrument, and a water distribution channel and a pressure measurement channel of the water distributor are respectively positioned between the two packing parts; the underground testing and adjusting instrument is also provided with an inner flow channel, the inlet of the inner flow channel is positioned above the upper sealing part, the outlet of the inner flow channel is arranged between the upper sealing part and the middle sealing part, and the outlet of the inner flow channel is communicated with a water distribution channel of the water distributor; the underground measuring and adjusting instrument is also provided with an external pressure sensor, the external pressure sensor tests the pressure between the middle sealing part and the lower sealing part through an external pressure testing channel, and the external pressure testing channel is communicated with a pressure measuring channel of the water distributor; the underground testing and adjusting instrument is also provided with an internal pressure sensor which tests the pressure in the oil pipe through an internal pressure testing channel; the underground testing and adjusting instrument is also provided with an inner flow testing unit which tests the water injection quantity flowing through the inner flow channel; the underground testing and adjusting instrument is also provided with an external flow testing unit, the external flow testing unit is positioned above a bridge type channel of the water distributor, and the external flow testing unit tests the flow passing through the external flow testing unit and the annular space of the oil pipe.

As a possible embodiment, the water distributor is provided with a switch main body, the switch main body is provided with a central hole, an axial bypass hole is arranged outside the central hole, and radial injection distribution outer holes and pressure measurement outer holes are arranged up and down along a central angle of 90-180 degrees in the circumferential direction of the side wall of the switch main body; the rotating cylinder is coaxially arranged in the central hole and is axially fixed, a radial injection allocation inner hole and a pressure measurement inner hole are arranged on the side wall of the rotating cylinder, the injection allocation inner hole and the pressure measurement inner hole are arranged on the same radial line, and the distance and the axial height between the injection allocation inner hole and the pressure measurement inner hole respectively correspond to the injection allocation outer hole and the pressure measurement outer hole; arranging a injection allocation hole sealing ring on the outer wall of the rotary cylinder around the injection allocation inner hole; a pressure measuring hole sealing ring is arranged on the outer wall of the rotary cylinder around the pressure measuring inner hole (324); the upper part of the rotary cylinder is provided with a rotary groove, and a torsion arm of a circumferential positioning mechanism of the underground measuring and adjusting instrument is inserted into the rotary groove; the lower joint is fixedly connected with the switch main body, a lower joint center hole is formed in the lower joint, the anti-rotation sleeve is fixedly installed in the lower joint center hole and is coaxial with the rotating cylinder, an anti-rotation groove is formed in the side wall of the anti-rotation sleeve, and a rotating arm of a rotating mechanism of the underground testing and adjusting instrument is inserted into the anti-rotation groove; and a lower bypass hole is arranged around the central hole of the lower joint.

As a preferred embodiment, the injection and pressure measuring outer holes of the water distributor are circumferentially arranged at a 180-degree central angle.

As a preferred embodiment, the rotating cylinder (302) of the water distributor is provided with a rotating positioning mechanism.

As a preferred embodiment, the rotary positioning mechanism comprises a radial screw arranged on the rotary cylinder, a positioning screw and a second positioning screw axially arranged on the switch main body, when the radial screw is in rotary contact with the positioning screw, the water distribution channel is opened, the pressure measuring channel is closed, and when the radial screw is in rotary contact with the second positioning screw, the water distribution channel is closed, and the pressure measuring channel is opened.

As a preferred embodiment, the rotation positioning mechanism includes a radial screw and a radial screw two mounted on the rotary cylinder, and a positioning screw axially mounted on the switch main body, when the radial screw rotates and contacts with the positioning screw, the water distribution channel is opened, the pressure measurement channel is closed, and when the radial screw two rotates and contacts with the positioning screw, the water distribution channel is closed, and the pressure measurement channel is opened.

As a preferred embodiment, a first back ring is arranged on the outer wall of the rotary cylinder and is circumferentially symmetrical to the injection hole sealing ring, and a second back ring is arranged on the outer wall of the rotary cylinder and is circumferentially symmetrical to the pressure measuring hole sealing ring.

As a preferred embodiment, a check valve is arranged on the outer hole of the dispensing nozzle in the side wall of the switch main body.

As a possible embodiment, the downhole measurement and adjustment instrument comprises an internal flow testing unit, a positioning unit, a packing unit and a pressure testing short section which are sequentially connected from top to bottom, wherein the internal flow testing unit comprises the internal flow short section, the positioning short section comprises the positioning unit, the packing short section comprises the packing unit and the pressure testing short section are respectively provided with a coaxial central through hole, a mandrel penetrates through the central through hole, and the mandrel is connected with a mandrel driving motor through a coupler; the mandrel is tubular and is provided with an electric wire passing through; the internal flow testing unit comprises an internal flow shell which is sleeved outside the internal flow nipple and forms a sealing cavity, the internal flow sensor is arranged in the sealing cavity, an upper internal flow annulus is formed between the mandrel and a central through hole of the internal flow nipple, and an internal flow inlet which is communicated with the upper internal flow annulus is arranged at the upper part of the internal flow nipple; the positioning unit comprises an axial positioning mechanism and a circumferential positioning mechanism which are arranged on the positioning short section, and an axial inner flow side hole is arranged on the side wall of the positioning short section and is used as a part of an inner flow channel; the packing unit comprises three packing parts and a setting mechanism thereof, wherein the setting mechanism comprises a setting thread arranged on the mandrel, a setting block connected with the mandrel through the setting thread, an extrusion ring sleeved on the periphery of the packing short section together with the packing parts, and a penetrating nail for fixing the extrusion ring and the setting block; a penetrating groove is formed in the side wall of the packing nipple, and a penetrating nail penetrates through the penetrating groove to fixedly connect the packing block with the extrusion ring; the central through hole of the packing nipple is a shoulder hole with the diameter expanded up and down, the mandrel and the diameter expanded parts of the upper part and the lower part of the central through hole respectively form a lower inner flow annulus and a lower pressure transmission annulus, and the setting block is arranged in the lower inner flow annulus and the lower pressure transmission annulus in a splitting manner; the rotating direction of the setting thread is adapted to the moving direction of the setting block; the pressure testing nipple is provided with an external pressure testing side hole, the upper end of the external pressure testing side hole is communicated with the lower pressure transmission annulus, and the lower end of the external pressure testing side hole is provided with an external pressure sensor; the pressure test nipple is also provided with an internal pressure test channel, the upper end of the internal pressure test channel is opened on the outer wall of the pressure test nipple, and the lower end of the internal pressure test channel is provided with an internal pressure sensor; the lower motor sleeve is connected below the pressure testing nipple, a rotating mechanism driving motor installed in the lower motor sleeve is connected with a rotating mechanism through a coupler, and the rotating mechanism is arranged at the lowest end of the underground testing and adjusting instrument.

As a possible embodiment, the upper setting block and the middle setting block are installed in the lower inner flow annulus, and the lower setting block is installed in the lower pressure transfer annulus; the upper and middle setting threads are opposite in direction of rotation.

As a possible embodiment, the upper setting block is installed in the lower internal flow annular space, and the middle setting block and the lower setting block are installed in the lower conveying annular space; the middle setting thread and the lower setting thread are opposite in rotation direction.

As a preferred embodiment, the internal flow sensor is an electromagnetic flow meter, the setting thread is a trapezoidal thread, and the sealing element is a compression type rubber cylinder.

The use method of the integrated flow-collecting bridge type testing, adjusting, inspecting, sealing and injecting system comprises the step that the integrated flow-collecting bridge type testing, adjusting, inspecting, sealing and injecting system is installed in a layered water injection well.

As a possible embodiment, the measuring and adjusting method comprises the following operation steps of using a cable to lower the underground measuring and adjusting instrument from the inside of an oil pipe to a position above a water distributor needing measuring and adjusting, and operating and starting a mandrel driving motor or a rotating mechanism driving motor through a ground control unit:

a. starting a mandrel driving motor to drive a mandrel to rotate, so that an axial positioning mechanism extends out, and a downhole testing and adjusting instrument is lowered, so that a positioning claw of the axial positioning mechanism falls on the upper end of a rotary cylinder of the water distributor;

b. starting a rotating mechanism driving motor to drive the rotating mechanism to rotate, so that a rotating arm of the rotating mechanism is inserted into the anti-rotation groove, the rotating mechanism is circumferentially fixed by a lower connector connected with an oil pipe, other parts of the underground measuring and adjusting instrument except the rotating mechanism rotate under the reaction force of the rotating mechanism, and a torsion arm of a circumferential positioning mechanism is automatically inserted into a rotating groove of the rotating cylinder and drives the rotating cylinder to rotate;

c. the mandrel driving motor continues to rotate to drive the mandrel to rotate, and three sealing elements are set;

d. adjusting injection allocation amount operation: starting a rotating mechanism to drive a motor to drive a rotating cylinder to rotate, and adjusting the relative overlapping area of an injection allocation inner hole and an injection allocation outer hole to adjust the injection allocation amount;

e. and (3) seal checking and pressure measuring operation: starting a rotating mechanism to drive a motor to drive a rotating cylinder to rotate, so that a pressure measuring inner hole is opposite to a pressure measuring outer hole, and at the moment, a pressure measuring channel is opened and a water distribution channel is closed; the water injection quantity and the water injection pressure are adjusted on the ground, and the pressure P of the corresponding oil layer of the water distributor is measured by an external pressure sensor _{Outer cover} Measuring the pressure P in the oil pipe by means of an internal pressure sensor _{Inner part} 。

Compared with the prior art, the technical advantages of the invention at least comprise:

1. the device of the invention is provided with three sealing parts and a setting mechanism thereof on the underground measuring and adjusting instrument, and a water distribution channel and a pressure measuring channel which are matched with each other are arranged on a matched water distributor, so that the device can carry out the operation of measuring pressure and checking seal for a certain water injection layer besides the operation of measuring and adjusting water injection layer by layer. The underground measuring and adjusting instrument can complete all operations by one-time descending, and has the advantages of high operation timeliness, simpler process and less operation cost.

2. The device provided by the invention is provided with the internal flow testing unit and the internal flow channel on the underground testing and adjusting instrument, and is matched with the water distributor disclosed by the invention, so that the flow-concentrating test is realized, the test precision is high, and the lower limit of the test is low.

3. The water distributor of the invention designs the cock valve type tubular linkage switch mechanism valve core, the part is few, the operation is reliable, the rotating cylinder is rotated by using the underground measuring and adjusting instrument of the invention, the switch of the water distribution channel and the pressure measuring channel can be realized.

4. Because the bridge type channel is arranged on the water distributor, when one oil layer is used for measuring and adjusting or measuring pressure, the water injection of other oil layers is not influenced, and the accuracy of flow adjustment is high.

5. Because the packing part uses the compression type rubber cylinder, the packing sealing pressure is high, and the work is reliable.

Drawings

A more complete appreciation of the invention and many of the attendant advantages thereof will be readily obtained as the same becomes better understood by reference to the following detailed description when considered in connection with the accompanying drawings, wherein the accompanying drawings are included to provide a further understanding of the invention and form a part of the specification, and the illustrated embodiments and descriptions thereof are intended to illustrate the invention and not to limit the same. Wherein:

fig. 1 is a schematic structural diagram of an integrated flow-collecting bridge type measuring, adjusting, inspecting, sealing and dispensing system.

Fig. 2 is a partially enlarged view of fig. 1.

Fig. 3 is a schematic view of the structure of the water distributor according to the invention (water distribution channel open in the figure).

Fig. 4 isbase:Sub>A sectional viewbase:Sub>A-base:Sub>A in fig. 3.

Fig. 5 is a schematic view of the structure of the water distributor of the present invention (showing the open state of the pressure measuring passage).

Fig. 6 is a sectional view B-B of fig. 5.

FIG. 7 is a schematic view of another embodiment of the water distributor switch positioning of the present invention.

FIG. 8 is a schematic view of a spin basket configuration illustrating circular seal ring grooves.

FIG. 9 is a schematic diagram of the downhole tool configuration, and this figure is also a sectional view B-B of FIG. 10.

Fig. 10 isbase:Sub>A sectional view taken along linebase:Sub>A-base:Sub>A of fig. 9.

Fig. 11 is a cross-sectional view C-C of fig. 9.

FIG. 12 is a schematic structural diagram of another preferred embodiment of a downhole tool.

In the figure:

101-ground control unit, 102-cable, 103-oil pipe, 104-casing, 105-downhole measuring and adjusting instrument, 106-packer II, 107-water distributor II, 108-bridge channel, 109-oil layer II, 110-packer III, 111-water distribution channel, 112-pressure measuring channel, 113-linkage switch,

120-external flow rate test unit, 121-internal pressure sensor, 122-internal flow rate test unit, 123-upper sealing member, 124-middle sealing member, 125-lower sealing member, 126-external pressure sensor, 127-internal pressure test channel, 128-internal flow channel, 129-external pressure test channel,

301-upper joint, 302-rotary cylinder, 303-radial screw, 304-fixed shoulder, 305-positioning screw, 306-switch main body, 307-injection allocation inner hole, 308-valve seat, 309-injection allocation outer hole, 310-valve rod, 311-spring, 312-blind plug, 313-fixed nut, 314-lower joint, 315-anti-rotation sleeve, 316-lower bypass hole, 317-anti-rotation groove, 318-rotation groove, 319-injection allocation hole sealing ring, 320-first back ring, 321-pressure hole sealing ring, 322-second back ring, 323-pressure measurement outer hole, 324-pressure measurement inner hole, 3051-positioning screw II, 401-upper bypass hole, 3031-radial screw II,

900-control unit, 901-internal flow nipple, 902-internal flow inlet, 903-internal flow housing, 904-internal flow sensor, 905-upper internal flow annulus, 906-mandrel, 907-internal flow side hole, 908-positioning nipple, 909-axial positioning mechanism, 910-axial positioning thread, 911-circumferential positioning mechanism, 912-upper setting thread, 913-upper setting block, 914-upper crossing nail, 915-upper pressing ring, 916-upper crossing groove, 917-middle setting block, 918-middle crossing nail, 919-middle pressing ring, 920-middle setting thread, 921-sealing nipple, 922-lower setting thread, 923-lower crossing groove, 924-lower setting block, 925-lower crossing nail, 926-lower pressing ring, 927-pressure testing nipple, 928-external pressure testing side hole, 929-lower mandrel sleeve, 930-drive motor, 931-rotation mechanism drive motor, 932-rotation mechanism, 933-lower internal flow pressure transmission annulus, 934-lower pressure transmission unit, 2000-internal flow positioning unit, 3000-sealing unit,

1201-upper motor cover.

Detailed Description

In the present specification and claims, the terms "upper" and "lower" in terms of positional relationship are described in terms of positional relationship in a state where the apparatus is run into a well. When the relation of inner, outer or inner and outer of the pipe is described, the small radius is inner or inner, and the large radius is outer. The parts with seals in the drawings are shown in the figures and are not described in detail in the following description.

In order to make the technical solutions and advantages of the present invention clearer, the following will describe embodiments of the present invention in further detail with reference to the accompanying drawings.

Referring to fig. 1 and fig. 2, the invention is a general view of the integrated flow-concentrating bridge type testing, regulating, sealing and dispensing system, which comprises two parts of a downhole separate-zone water injection string and a testing and regulating system.

The downhole separate layer water injection pipe column is arranged in a casing 104 and comprises a packer and a water distributor which are connected by an oil pipe 103, one water distributor is arranged corresponding to each oil layer, one packer is arranged above each oil layer, as shown in the figure, a second water distributor 107 and a second packer 106 are arranged corresponding to a second oil layer 109, and a third packer 110 is arranged below the second oil layer and corresponding to a next oil layer. Fig. 1 shows the case of three oil layers for separate injection, and the separate injection string structure of more oil layers is added with a packer and a water distributor corresponding to the oil layer. Generally, a check valve is also installed at the lower end of the separate layer water injection string. In addition to the water distributor of the present invention, other downhole tools for zonal injection strings are known in the art.

The tone measuring system includes a surface control unit 101 installed at the surface, a cable 102, and a downhole tone measuring instrument 105.

The ground control unit 101 is used for receiving and displaying test data uploaded by the downhole testing and adjusting instrument, including flow and pressure data, and sending a command for starting or stopping the rotation of the motor to the downhole testing and adjusting instrument.

Electrical cables are known in the art.

The water distributor is provided with a bridge type channel 108, a water distribution channel 111, a pressure measuring channel 112 and a linked switch 113; the linked switch simultaneously controls the water distribution channel and the pressure measuring channel, so that the water distribution channel and the pressure measuring channel are always in a one-on one-off or full-off state; the ganged switch is driven by a circumferential positioning mechanism 911 of the underground measuring and adjusting instrument;

the periphery of the underground measuring and adjusting instrument is provided with three sealing parts, namely an upper sealing part 123, a middle sealing part 124 and a lower sealing part 125, the sealing parts seal and separate the annular space between the water distributor and the underground measuring and adjusting instrument, and the water distribution channel 111 and the pressure measurement channel 112 of the water distributor are respectively positioned between the two sealing parts; the underground measuring and adjusting instrument is also provided with an inner flow channel 128, the inlet of the inner flow channel 128 is positioned above the upper sealing part 123, the outlet of the inner flow channel 128 is arranged between the upper sealing part 123 and the middle sealing part 124, and the outlet of the inner flow channel 128 is communicated with the water distribution channel 111 of the water distributor;

the underground measuring and adjusting instrument is also provided with an external pressure sensor 126, the external pressure sensor 126 tests the pressure between the middle sealing part 124 and the lower sealing part 125 through an external pressure testing channel 129, and the external pressure testing channel 129 is communicated with the pressure testing channel 112 of the water distributor; when the pressure sensing channel is open, the external pressure sensor 126 measures the pressure in the annulus outside the distributor. If the packers above and below the oil layer are well sealed, the pressure of the annulus outside the water distributor is the pressure of the oil layer.

The underground testing and adjusting instrument is also provided with an internal pressure sensor 121, and the internal pressure sensor 121 tests the pressure in the oil pipe through an internal pressure testing channel 127;

the underground measuring and adjusting instrument is also provided with an inner flow testing unit 122 and an inner flow channel 128, wherein the inner flow testing unit is used for testing the water injection quantity flowing through the inner flow channel (the water injection quantity refers to daily water injection quantity in engineering, the same applies below), namely the water injection quantity of an oil layer corresponding to the water distributor;

the downhole testing and adjusting instrument is further provided with an external flow testing unit 120, the external flow testing unit is located above the bridge-type channel 108 of the water distributor, the external flow testing unit tests flow passing through the annular space between the external flow testing unit and the oil pipe, and the measured flow is the total water injection amount of an oil layer corresponding to the water distributor and an oil layer below the water distributor.

Referring to fig. 3 and 5, the water distributor is provided with a switch main body 306, the switch main body is provided with a central hole, an axial upper bypass hole 401 is arranged outside the central hole, and a radial injection distribution outer hole 309 and a pressure measurement outer hole 323 are arranged up and down on the side wall of the switch main body in a circumferential direction at a central angle of 90-180 degrees; the circumferential directions of the injection allocation outer hole 309 and the pressure measurement outer hole 323 of the water distributor are optimally arranged in a 180-degree central angle. The dispensing outer orifice 309 may be a straight radial orifice, like the manometric outer orifice. In order to prevent the formation water from flowing back into the water distributor when the injection is stopped, a check valve may be provided in the channel of the injection allocation outer hole 309, as shown in fig. 3, as a possible example, the check valve is axially arranged in the side wall of the switch body 306, the flow channel of the injection allocation outer hole 309 has two right-angle turns, and a valve seat 308 is provided in the axial flow channel thereof, the structure of the check valve is known in the art, and the check valve is a component comprising: a valve stem 310, a spring 311 and a blind 312.

The rotary cylinder 302 is coaxially installed in the central hole of the switch main body 306 and is axially fixed, the side wall of the rotary cylinder is provided with a radial injection allocation inner hole 307 and a pressure measurement inner hole 324, the injection allocation inner hole 307 and the pressure measurement inner hole 324 are arranged on the same radial line, and the distance and the axial height between the injection allocation inner hole 307 and the pressure measurement inner hole 324 correspond to the injection allocation outer hole 309 and the pressure measurement outer hole 323 respectively; a injection allocation hole sealing ring 319 is arranged on the outer wall of the rotary cylinder around the injection allocation inner hole 307; a pressure measuring hole sealing ring 321 is provided on the outer wall of the rotary cylinder around the pressure measuring hole 324. The cross-section of the dispensing hole sealing ring 319 and the pressure measuring hole sealing ring 321 may be "O" shaped, rectangular or trapezoidal, and the planar shape thereof may be circular, oval, square, polygonal, etc., and as a preferred embodiment, the cross-sectional shape thereof is trapezoidal and the planar shape thereof is circular, as shown in fig. 3 and 8.

The inner dispensing hole 307 and the outer dispensing hole 309 jointly form a water distribution channel 111, and the inner pressure measuring hole 324 and the outer pressure measuring hole 323 jointly form a pressure measuring channel 112.

The linkage switch 113 comprises the following parts and structures: the rotary cylinder 302, a dispensing inner hole 307 and a pressure measuring inner hole 324, a dispensing hole sealing ring 319 and a pressure measuring hole sealing ring 321 which are arranged on the rotary cylinder, and the switch main body 306, a dispensing outer hole 309 and a pressure measuring outer hole 323 which are arranged on the switch main body. The gang switch 113 is a cock-type switch, and the water distribution passage 111 and the pressure measurement passage 112 are simultaneously controlled by rotating the rotary cylinder 302.

The upper part of the rotary cylinder 302 is provided with a rotary groove 318, and a torsion arm of a circumferential positioning mechanism 911 of the downhole measuring and adjusting instrument is inserted into the rotary groove 318 to drive the rotary cylinder 302 to rotate. The rotation of the rotary cylinder 302 can adjust the relative overlapping area of the inner injection allocation hole 307 and the outer injection allocation hole 309 to adjust the injection amount, and can also close the water distribution channel 111 and open the pressure measurement channel 112.

The rotating drum 302 may be rotated by controlling the rotation angle with a downhole tool. As a preferred example, the rotating barrel 302 of the described water distributor may also be provided with a rotational positioning mechanism in order to provide an indication of the operation of the surface control unit.

As a possible example, see fig. 4 and 6, which show the optimal arrangement of the injection outer hole 309 and the pressure outer hole 323 of the described water distributor with a 180 ° central angle in the circumferential direction. The rotary positioning mechanism comprises a radial screw 303 arranged on the rotary cylinder 302, and a positioning screw 305 and a second positioning screw 3051 axially arranged on the switch main body 306, when the radial screw 303 rotates to contact the positioning screw 305, the injection allocation inner hole 307 is oppositely communicated with the injection allocation outer hole 309, the pressure measurement inner hole 324 is not communicated with the pressure measurement outer hole 323, at the moment, the water distribution channel 111 is opened, and the pressure measurement channel 112 is closed; when the radial screw 303 is rotated to contact the second positioning screw 3051, the inner injection allocation hole 307 is not communicated with the outer injection allocation hole 309, the inner pressure measurement hole 324 is relatively communicated with the outer pressure measurement hole 323, and at the moment, the water distribution passage 111 is closed and the pressure measurement passage 112 is opened.

As a possible example, see fig. 7, which shows the described optimal arrangement of the injection outer hole 309 and pressure outer hole 323 of the water distributor with a 180 ° central angle in the circumferential direction. The rotational positioning mechanism comprises a radial screw 303 and a radial screw pair 3031 which are arranged on the rotary cylinder 302, and a positioning screw 305 which is axially arranged on the switch main body 306. When the radial screw 303 rotates to contact the positioning screw 305, the injection allocation inner hole 307 is relatively communicated with the injection allocation outer hole 309, the pressure measurement inner hole 324 is not communicated with the pressure measurement outer hole 323, at the moment, the water distribution channel 111 is opened, and the pressure measurement channel 112 is closed; when the radial screw two 3031 rotates to contact the positioning screw 305, the injection allocation inner hole 307 is not communicated with the injection allocation outer hole 309, the pressure measurement inner hole 324 is relatively communicated with the pressure measurement outer hole 323, and at the moment, the water distribution channel 111 is closed and the pressure measurement channel 112 is opened.

As a preferable example, in order to reduce the rotation resistance of the rotary cylinder 302, a first back ring 320 is arranged on the outer wall of the rotary cylinder 302 and circumferentially symmetrical to the injection hole sealing ring 319, and a second back ring 322 is arranged on the outer wall of the rotary cylinder 302 and circumferentially symmetrical to the pressure hole sealing ring 321. The shape of the first back ring and the second back ring is completely the same as that of the injection hole sealing ring and the pressure measuring hole sealing ring.

The lower joint 314 is fixedly connected with the switch main body 306, a lower joint center hole is arranged in the lower joint, the anti-rotation sleeve 315 is fixedly arranged in the lower joint center hole and is coaxial with the rotary cylinder 302, an anti-rotation groove 317 is arranged on the side wall of the anti-rotation sleeve 315, and a rotating arm of a rotating mechanism 932 of the down-hole measuring and adjusting instrument is inserted into the anti-rotation groove 317; a lower bypass hole 316 is provided around the lower joint center hole.

The upper bypass hole 401 and the lower bypass hole 316 are part of the bridge-type channel 108, and during measurement and adjustment operation, injected water flows through the upper bypass hole and the lower bypass hole and enters an oil layer below the water distributor of the stage.

Referring to fig. 9, 10 and 11, the downhole logging instrument includes an internal flow testing unit 122, a positioning unit 2000, a packing unit 3000 and a pressure testing nipple 927, which are sequentially connected from top to bottom. The internal flow test unit comprises an internal flow nipple 901, the positioning nipple 908 comprised by the positioning unit, the packing nipple 921 comprised by the packing unit and the pressure test nipple 927 which are all provided with coaxial central through holes, and the mandrel 906 passes through the central through holes. The mandrel 906 is connected with the mandrel driving motor 930 through a coupler; the mandrel is tubular and has an electrical wire passing therethrough. In order to prevent the core shaft from twisting off the wires passing through it when it is rotated, as a preferred example, rotating electrical slip rings are mounted at both ends of the core shaft. The structure of the rotating electric slip ring is known in the prior art, and is referred to the Chinese patent 'bidirectional sealed collector type flow regulator', application number 201510973113.4, application date 2015.12.22. The spindle drive motor 930 may be provided at the lower end of the spindle as shown in fig. 9, or may be provided at the upper end of the spindle as shown in fig. 12.

The internal flow test unit 122 comprises an internal flow shell 903 which is sleeved outside the internal flow nipple 901 and forms a sealed cavity, an internal flow sensor 904 is arranged in the sealed cavity, an upper internal flow annulus 905 is formed between the mandrel 906 and a central through hole of the internal flow nipple 901, and an internal flow inlet 902 is formed in the upper portion of the internal flow nipple 901 and is communicated with the upper internal flow annulus 905. The internal flow sensor 904 may be electromagnetic, vortex street, ultrasonic, etc., and among them, an electromagnetic flow sensor is preferable. Typically, the probe of the flow sensor is intended to be in contact with the injected water through the inner wall of the sealed cavity, and a flow sensor downhole in a water injection well is known in the art.

Positioning unit 2000 includes an axial positioning mechanism 909 and a circumferential positioning mechanism 911 mounted on positioning nipple 908. The axial positioning mechanism 909 and the circumferential positioning mechanism 911 are known in the art, see the chinese patent "bidirectional sealed collector type flow regulator", application No. 201510973113.4, application No. 2015.12.22. An axial inner flow side port 907, shown in cross-section in figure 10, is provided in the sidewall of the locating sub 908 as part of the inner flow channel 128.

The packing unit 3000 comprises three packing members (an upper packing member 123, a middle packing member 124 and a lower packing member 125) and a setting mechanism thereof, wherein the setting mechanism comprises setting threads (an upper setting thread 912, a middle setting thread 920 and a lower setting thread 922) arranged on a mandrel 906, setting blocks (an upper setting block 913, a middle setting block 917 and a lower setting block 924) connected with the mandrel through the setting threads, extrusion rings (a lower extrusion ring 915, a middle extrusion ring 919 and a lower extrusion ring 926) which are sleeved on the periphery of a packing nipple 921 together with the packing members, and penetrating nails (an upper penetrating nail 914, a middle penetrating nail 918 and a lower penetrating nail 925) for fixing the extrusion rings and the setting blocks; a penetrating groove (an upper penetrating groove 916 and a lower penetrating groove 923) is formed in the side wall of the packing nipple 921, and a penetrating nail penetrates through the penetrating groove to fixedly connect the packing block and the extrusion ring; the central through hole of the packing nipple 921 is a shoulder hole with diameter expanded up and down, the mandrel 906 and the upper and lower diameter expanded parts of the central through hole respectively form a lower inner flow annulus 933 and a lower pressure transmission annulus 934, and the setting blocks (913, 917, 924) are respectively arranged in the lower inner flow annulus 933 and the lower pressure transmission annulus 934.

The setting mechanisms of the three sealing members are the same, except that the mounting positions of the sealing members are different, the moving and extruding directions of the setting mechanisms are different, and the rotating direction of the setting threads 920 is matched with the moving direction of the setting block, as in the setting mechanism of the upper sealing member in fig. 9, during the setting process, the mandrel rotates, and the upper setting threads push the upper setting block and the upper extruding ring to compress the upper sealing member upwards. Both the middle and lower enclosures in fig. 9 are compressed downward.

As one possible example, referring to FIG. 9, the upper 913 and middle seat blocks 917 are installed in the lower inner flow annulus 933, and the lower seat block 924 is installed in the lower annulus 934; the upper setting thread 912 and the middle setting thread 920 are counter-rotating.

As another possible example, referring to fig. 12, the upper setting block 913 is installed in the lower inner flow annulus 933, and the middle setting block 917 and the lower setting block 924 are installed in the lower annulus 934; the middle setting thread 920 and the lower setting thread 922 are opposite in direction.

As a preferred embodiment, in order to increase the transmission efficiency, the setting thread is preferably a trapezoidal thread.

The sealing element can be a leather cup or a compression rubber cylinder, and the compression rubber cylinder is the best.

Referring to fig. 9, the inner flow path 128 is a flow path through which the injected water enters along an arrow of the inner flow inlet 902, and includes: an inner flow inlet 902, an upper inner flow annulus 905, inner flow side holes 907, a lower inner flow annulus 933, and upper pass-through slots 916.

The pressure testing short section 927 is provided with an external pressure testing side hole 928, the upper end of the external pressure testing side hole is communicated with a lower pressure transmission annulus 934, and the lower end of the external pressure testing side hole is provided with an external pressure sensor 126; the outer pressure test side holes 928 and the lower pressure annulus 934 together form the outer pressure test channel 129.

Pressure test nipple 927 still is equipped with interior pressure test channel 127, presses test channel upper end opening in pressure on the pressure test nipple outer wall, and pressure sensor 121 is pressed in the lower extreme installation.

The internal pressure sensor 121 may also be installed at the upper part of the downhole gauge, as shown in fig. 12, and an internal pressure test passage 127 is provided on the side wall of the upper motor casing 1201 and the internal pressure sensor 121 is installed.

The lower motor sleeve 929 is connected below the pressure test short section 927, a rotating mechanism driving motor 931 arranged in the lower motor sleeve 929 is connected with a rotating mechanism 932 through a coupler, the rotating mechanism is arranged at the lowest end of the underground measuring and adjusting instrument, and a speed reducing mechanism can be connected between the coupler and the rotating mechanism according to the requirements of rotating speed and torque. The rotating mechanism and the reducing mechanism are known technologies, and refer to the chinese patent "bidirectional sealed flow-collecting type flow regulator", application No. 201510973113.4, application date 2015.12.22.

The test data of the underground testing and adjusting instrument can be directly transmitted to the ground control unit 101 through a cable, and the ground control unit can also directly start and stop the motor of the underground testing and adjusting instrument. As a preferred example, a control unit 900 may be disposed at an upper portion of the down-hole measurement instrument, and is configured to collect test signals of the flow sensor and the pressure sensor, transmit the obtained test signals to the surface control unit through a cable, and receive an instruction from the surface control unit to start and stop the corresponding motors.

The external flow rate testing unit 120 may be connected to the downhole measurement and adjustment instrument as a flow rate testing short section, or may be integrated with the downhole measurement and adjustment instrument as a part of the downhole measurement and adjustment instrument. The external flow testing unit can select an electromagnetic external flow meter.

The invention discloses a using method of an integrated flow-collecting bridge type measuring, adjusting, checking and injecting system, wherein the measuring and adjusting method comprises the following steps of using a cable to lower a downhole measuring and adjusting instrument from the inside of an oil pipe to a position above a water distributor needing measuring and adjusting, operating and starting a mandrel driving motor 930 or a rotating mechanism driving motor 931 through a ground control unit, and further comprising the following operation procedures:

a. starting a mandrel driving motor to drive a mandrel to rotate, so that an axial positioning mechanism extends out, and a downhole testing and adjusting instrument is lowered, so that a positioning claw of the axial positioning mechanism falls on the upper end of a rotary cylinder of the water distributor;

b. starting a rotating mechanism driving motor to drive the rotating mechanism to rotate, so that a rotating arm of the rotating mechanism is inserted into an anti-rotation groove 317, the rotating mechanism is circumferentially fixed by a lower connector connected with an oil pipe at the moment, other parts of the underground testing and adjusting instrument except the rotating mechanism rotate under the reaction force of the rotating mechanism, and a torsion arm of a circumferential positioning mechanism 911 is automatically inserted into a rotating groove 318 of a rotating cylinder and drives the rotating cylinder to rotate;

c. the mandrel driving motor continues to rotate to drive the mandrel to rotate, and three sealing elements are set;

d. adjusting the injection amount: starting a rotating mechanism to drive a motor to drive a rotating cylinder to rotate, and adjusting the relative overlapping area of an injection allocation inner hole 307 and an injection allocation outer hole 309 to adjust the injection allocation amount;

e. and (3) seal checking and pressure measuring operation: the rotating mechanism is started to drive the motor to drive the rotating cylinder to rotate so as to measure the pressure in the pressure measuring cylinderThe hole 324 is opposite to the pressure measuring outer hole 323, at this time, the pressure measuring channel 112 is opened, and the water distribution channel 111 is closed; adjusting water injection quantity and water injection pressure on the ground, and measuring pressure P of corresponding oil layer of the water distributor through an external pressure sensor _{Outer cover} Measuring the pressure P in the oil pipe by means of an internal pressure sensor _{Inner part} 。

The tested flow and pressure can be drawn into flow-time and pressure-time curves, and the sealing state of the packer can be judged through comparative analysis.

The existing test cable has the problems of low strength, high cost, insufficient insulation performance and the like, and a special test cable is specially developed for the purpose. The cable 102 comprises three layers from outside to inside, wherein the first layer is a continuous steel pipe, the second layer is an insulating layer, the center is a copper conductor, and the insulating layer comprises polytetrafluoroethylene on the outer layer and polypropylene on the inner layer. As a preferred embodiment, the continuous steel pipe is a stainless steel material 2507, which has a thickness of 0.7mm and an outer diameter of 4mm. In one possible implementation, the copper conductor is an enameled single-core copper conductor.

It will be apparent that those skilled in the art can make many modifications and variations based on the spirit of the present invention.

Claims (12)

1. The integrated flow-collecting bridge type measurement, regulation, seal-checking and injection-distributing system comprises a water distributor and an underground measurement and regulation instrument, and is characterized in that the water distributor is provided with a bridge type channel (108), a water distribution channel (111), a pressure measurement channel (112) and a linked switch (113); the linked switch controls the water distribution channel and the pressure measuring channel at the same time, so that the water distribution channel and the pressure measuring channel are always in an on-off or full-off state; the linked switch is driven by a circumferential positioning mechanism (911) of the underground measuring and adjusting instrument; the water distributor is provided with a switch main body (306), the switch main body is provided with a central hole, an axial side-pass hole (401) is arranged outside the central hole, and a radial injection distribution outer hole (309) and a pressure measurement outer hole (323) are arranged up and down on the side wall of the switch main body in the circumferential direction at a central angle of 90-180 degrees; the rotating cylinder (302) is coaxially installed in the central hole and is axially fixed, a radial injection allocation inner hole (307) and a pressure measurement inner hole (324) are formed in the side wall of the rotating cylinder, the injection allocation inner hole (307) and the pressure measurement inner hole (324) are arranged on the same radial line, and the distance and the axial height between the injection allocation inner hole (307) and the pressure measurement inner hole (324) correspond to the injection allocation outer hole (309) and the pressure measurement outer hole (323) respectively; a injection allocation hole sealing ring (319) is arranged on the outer wall of the rotary cylinder around the injection allocation inner hole (307); a pressure measuring hole sealing ring (321) is arranged on the outer wall of the rotary cylinder around the pressure measuring inner hole (324); a rotating groove (318) is formed in the upper portion of the rotating cylinder (302), and a torsion arm of a circumferential positioning mechanism (911) of the downhole measuring and adjusting instrument is inserted into the rotating groove (318); the lower joint (314) is fixedly connected with the switch main body (306), a lower joint center hole is formed in the lower joint, the anti-rotation sleeve (315) is fixedly installed in the lower joint center hole and is coaxial with the rotary cylinder (302), an anti-rotation groove (317) is formed in the side wall of the anti-rotation sleeve (315), and a rotating arm of a rotating mechanism (932) of the underground measurement and adjustment instrument is inserted into the anti-rotation groove (317); a lower bypass hole (316) is arranged around the central hole of the lower joint; the periphery of the underground measuring and adjusting instrument is provided with three sealing parts (123, 124 and 125), the sealing parts seal and separate an annular space between the water distributor and the underground measuring and adjusting instrument, and a water distribution channel (111) and a pressure measurement channel (112) of the water distributor are respectively positioned between two sealing parts; the underground measuring and adjusting instrument is also provided with an inner flow channel (128), the inlet of the inner flow channel (128) is positioned above the upper sealing part (123), the outlet of the inner flow channel (128) is arranged between the upper sealing part (123) and the middle sealing part (124), and the outlet of the inner flow channel (128) is communicated with the water distribution channel (111) of the water distributor; the underground measuring and adjusting instrument is also provided with an external pressure sensor (126), the external pressure sensor (126) tests the pressure between the middle sealing part (124) and the lower sealing part (125) through an external pressure testing channel (129), and the external pressure testing channel (129) is communicated with a pressure measuring channel (112) of the water distributor; the underground testing and adjusting instrument is also provided with an internal pressure sensor (121), and the internal pressure sensor (121) tests the pressure in the oil pipe through an internal pressure testing channel (127); the underground testing and adjusting instrument is also provided with an inner flow testing unit (122), and the inner flow testing unit tests the water injection quantity flowing through the inner flow channel; the underground testing and adjusting instrument is further provided with an external flow testing unit (120), the external flow testing unit is located above a bridge type channel (108) of the water distributor, and the external flow testing unit tests flow flowing through the external flow testing unit and the annular space of the oil pipe.

2. The integrated flow-concentrating bridge type metering, testing and sealing dispensing system as claimed in claim 1, wherein the dispensing outer orifice (309) and the pressure measuring outer orifice (323) of the water distributor are circumferentially arranged at a 180 ° central angle.

3. The integrated flow-concentrating bridge type metering, regulating, inspecting and dispensing system as claimed in claim 1, wherein the rotating cylinder (302) of the water distributor is provided with a rotational positioning mechanism.

4. The integrated flow-concentrating bridge type metering, testing and sealing dispensing system of claim 3, wherein the rotary positioning mechanism comprises a radial screw (303) mounted on the rotary cylinder (302), and a positioning screw (305) and a second positioning screw (3051) axially mounted on the switch body (306), when the radial screw (303) is in rotary contact with the positioning screw (305), the water distribution channel (111) is opened, the pressure measurement channel (112) is closed, and when the radial screw (303) is in rotary contact with the second positioning screw (3051), the water distribution channel (111) is closed, and the pressure measurement channel (112) is opened.

5. The integrated flow concentrating bridge type test-check-seal dispensing system of claim 3, wherein the rotary positioning mechanism comprises a radial screw (303) and a radial screw II (3031) which are mounted on the rotary cylinder (302), and a positioning screw (305) which is axially mounted on the switch main body (306), when the radial screw (303) is in rotary contact with the positioning screw (305), the water distribution channel (111) is opened, the pressure measurement channel (112) is closed, and when the radial screw II (3031) is in rotary contact with the positioning screw (305), the water distribution channel (111) is closed, and the pressure measurement channel (112) is opened.

6. The integrated manifold bridge type test, adjustment, seal and dispensing system according to claim 1, wherein a first back ring (320) is arranged on the outer wall of the rotary cylinder (302) and circumferentially symmetrical to the injection port sealing ring (319), and a second back ring (322) is arranged on the outer wall of the rotary cylinder (302) and circumferentially symmetrical to the pressure port sealing ring (321).

7. The integrated manifold bridge type metering, regulating, testing, sealing and dispensing system of claim 1, wherein a single flow valve is disposed in the dispensing outer orifice (309) in the sidewall of said switch body (306).

8. The integrated flow-concentrating bridge type testing, adjusting, sealing and dispensing system of claim 1, wherein the downhole testing and adjusting instrument comprises an internal flow testing unit (122), a positioning unit (2000), a packing unit (3000) and a pressure testing short section (927) which are sequentially connected from top to bottom, the internal flow testing unit comprises an internal flow short section (901), the positioning short section (908) comprises the positioning unit, the packing short section (921) comprises the packing unit and the pressure testing short section (927) are all provided with coaxial central through holes, a mandrel (906) passes through the central through hole, and the mandrel (906) is connected with a mandrel driving motor (930) through a coupler; the mandrel is tubular and is provided with an electric wire passing through;

the internal flow testing unit (122) comprises an internal flow shell (903) which is sleeved outside the internal flow nipple (901) and forms a sealed cavity, an internal flow sensor (904) is arranged in the sealed cavity, an upper internal flow annulus (905) is formed between a mandrel (906) and a central through hole of the internal flow nipple (901), and an internal flow inlet (902) which is communicated with the upper internal flow annulus (905) is formed in the upper part of the internal flow nipple (901); the positioning unit (2000) comprises an axial positioning mechanism (909) and a circumferential positioning mechanism (911) which are installed on the positioning short section (908), and an axial inner flow side hole (907) is arranged on the side wall of the positioning short section (908) and is used as a part of the inner flow channel (128); the packing unit (3000) comprises three packing parts (123, 124, 125) and a setting mechanism thereof, wherein the setting mechanism comprises setting threads (912, 920, 922) arranged on a mandrel (906), a setting block connected with the mandrel through the setting threads, a pressing ring (915, 919, 926) sleeved on the periphery of a packing short section (921) together with the packing parts, and penetrating nails (914, 918, 925) for fixing the pressing ring and the setting block, and the setting block comprises an upper setting block (913), a middle setting block (917) and a lower setting block (924); a through groove (916, 923) is formed in the side wall of the packing short section (921), and a through nail penetrates through the through groove to fixedly connect the setting block and the extrusion ring; the central through hole of the packing nipple (921) is a shoulder hole with expanded diameters from top to bottom, the mandrel (906) and the expanded diameter parts at the top and bottom of the central through hole respectively form a lower inner flow annulus (933) and a lower pressure transmission annulus (934), and the setting block is arranged in the lower inner flow annulus (933) and the lower pressure transmission annulus (934) in a splitting manner; the rotating direction of the setting thread (920) is adapted to the moving direction of the setting block; the pressure testing short section (927) is provided with an external pressure testing side hole (928), the upper end of the external pressure testing side hole is communicated with the lower pressure transmission annulus (934), and the lower end of the external pressure testing side hole is provided with an external pressure sensor (126); the pressure test short section (927) is also provided with an internal pressure test channel (127), the upper end opening of the internal pressure test channel is arranged on the outer wall of the pressure test short section, and the lower end is provided with an internal pressure sensor (121); the lower motor sleeve (929) is connected below the pressure testing short section (927), a rotating mechanism driving motor (931) installed in the lower motor sleeve (929) is connected with a rotating mechanism (932) through a coupler, and the rotating mechanism is arranged at the lowest end of the underground testing and adjusting instrument.

9. The integrated manifold bridge metering, testing, sealing and dispensing system of claim 8, wherein the upper setting block (913) and the middle setting block (917) are installed in the lower inner flow annulus (933), and the lower setting block (924) is installed in the lower pressure transfer annulus (934); the upper setting thread (912) and the middle setting thread (920) are opposite in direction of rotation.

10. The integrated manifold bridge metering, testing and sealing dispensing system according to claim 8, wherein the upper setting block (913) is installed in the lower inner flow annulus (933), and the middle setting block (917) and the lower setting block (924) are installed in the lower pressure transfer annulus (934); the middle setting thread (920) and the lower setting thread (922) are opposite in rotation direction.

11. The integrated manifold bridge test, seal, and dispense system of claim 8, wherein said internal flow sensor (904) is an electromagnetic flow meter.

12. The use method of the integrated flow-collecting bridge type measuring, adjusting, testing, sealing and dispensing system is characterized in that the measuring and adjusting method comprises the steps of descending a downhole measuring and adjusting instrument from the inside of an oil pipe to a position above a water distributor needing measuring and adjusting by a cable, operating and starting a mandrel driving motor (930) or a rotating mechanism driving motor (931) through a ground control unit, and further comprising the following operation procedures:

a. starting a mandrel driving motor to drive a mandrel to rotate, so that an axial positioning mechanism extends out, and a downhole testing and adjusting instrument is lowered, so that a positioning claw of the axial positioning mechanism falls on the upper end of a rotary cylinder of the water distributor;

b. starting a rotating mechanism driving motor to drive the rotating mechanism to rotate, so that a rotating arm of the rotating mechanism is inserted into an anti-rotation groove (317), the rotating mechanism is circumferentially fixed by a lower connector connected with an oil pipe at the moment, other parts of the downhole measuring and adjusting instrument except the rotating mechanism rotate under the reaction force of the rotating mechanism, and a torsion arm of a circumferential positioning mechanism (911) is automatically inserted into a rotating groove (318) of a rotating cylinder and drives the rotating cylinder to rotate;

c. the mandrel driving motor continues to rotate to drive the mandrel to rotate, and three sealing elements are set;

d. adjusting injection allocation amount operation: starting a rotating mechanism to drive a motor to drive a rotating cylinder to rotate, and adjusting the relative overlapping area of an injection allocation inner hole (307) and an injection allocation outer hole (309) to adjust the injection allocation amount;

e. and (3) seal checking and pressure measuring operation: starting a rotating mechanism to drive a motor to drive a rotating cylinder to rotate, so that a pressure measuring inner hole (324) is opposite to a pressure measuring outer hole (323), and at the moment, a pressure measuring channel (112) is opened, and a water distribution channel (111) is closed; adjusting water injection quantity and water injection pressure on the ground, and measuring pressure P of corresponding oil layer of the water distributor through an external pressure sensor _{Outer cover} ' TongtongThe over-internal pressure sensor measures the pressure P in the oil pipe _{Inner part} 。

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