CN112554852A

CN112554852A - Self-adaptive intelligent selective-firing switch for detonating underground perforating detonator

Info

Publication number: CN112554852A
Application number: CN202011559543.9A
Authority: CN
Inventors: 罗浪; 龙建全; 杨凯博
Original assignee: Xi'an Maoze Electronic Technology Co ltd
Current assignee: Xi'an Maoze Electronic Technology Co ltd
Priority date: 2020-12-25
Filing date: 2020-12-25
Publication date: 2021-03-26

Abstract

The invention discloses a self-adaptive intelligent selective-firing switch for detonating an underground perforating detonator, which mainly solves the problems that the existing intelligent selective-firing switch is complex in wiring mode and needs to manually distinguish the type of the detonator. The method comprises the following steps: the device comprises a communication transceiving module for processing signals in a modulation and demodulation mode, a temperature sensor, a power supply voltage acquisition circuit, a downward power supply driving circuit, a detonator excitation circuit, a detonator type identification module and an output type selection switch, wherein the detonator type identification module and the output type selection switch are arranged between a microprocessor and an output port; the intelligent selective-sending switch has independent fixed addresses, can be conducted step by step to form a multi-stage selective-sending switch, is provided with an independent detonator type identification module on each stage of selective-sending switch, and completes the communication work of an output line and a corresponding type detonator excitation circuit according to an identification result. The invention effectively improves the field working efficiency, simplifies the wiring mode and can adaptively detonate various detonators without introducing manual operation.

Description

Self-adaptive intelligent selective-firing switch for detonating underground perforating detonator

Technical Field

The invention belongs to the technical field of oil and gas exploitation, and further relates to an intelligent control technology of underground perforation, in particular to a self-adaptive intelligent selective switch for detonation of an underground perforation detonator, which can be used for underground equipment for exploitation of oil and gas fields.

Background

The combination of bridge plugs and perforations is the most widely used perforation completion mode in unconventional oil and gas reservoir development, and the mode can effectively improve the single well production. The cable conveying bridge-shooting combined technology utilizes cable pumping to finish bridge plug setting and multi-cluster perforation by one-time well descending, and has the advantages of no limitation of the number of layers of segmented fracturing, simple tool pipe column, difficult sand blocking, quick blockage relieving, obvious single-well production increasing effect and the like. In recent years, along with the acceleration of development steps of shale oil gas and dense oil gas, the importance of the transformation efficiency and effect of a fracturing reservoir is highlighted, the demand of bridge-perforating combined operation is greatly increased, and higher requirements are provided for the bridge plug and perforating combined operation technology and the process construction process. Products which do not need cable matching and can be compatible with various bridge plug igniters and perforating detonators are not found in related perforating detonator products in China at present.

At present, most foreign cable graded perforation and detonation controllers are complex to operate and do not accord with the operation habits of domestic operators. The domestic cable multi-stage perforation exploder has the defects of incompatibility with various igniters and detonators, risk of wrong explosion, strong cable dependence and the like. The specifications and lengths of the cables used by the logging teams are different, and the impedance matching on site is time-consuming and labor-consuming.

The conventional selective switch used in the prior art has strong dependence on cables, and when the impedance of the cables changes, the cables need to be matched manually. The existing mechanical hair selection switch has the defects of large volume, large contact force, poor stability and incapability of realizing random hair selection; the conventional electronic switch for selecting and transmitting is characterized in that the next-stage electronic switch for selecting and transmitting connected in series on the tool string is turned on one by one through the processor, and the electronic addressing mode is poor in stability and safety. In the utility model with application number 202020339630.2, entitled intelligent selective switch for cable transportation bridge plug and perforation combined operation, an intelligent selective switch is disclosed, which comprises a communication transceiver module for processing signals by adopting a modulation and demodulation mode, a temperature sensor connected to a microprocessor and used for monitoring downhole temperature in real time, and an ignition voltage output acquisition circuit; the intelligent selective-sending switch has independent fixed addresses and can be mutually connected in a step-by-step conduction mode to form a multi-stage selective-sending switch, each stage of selective-sending switch is provided with a magnetoelectric detonator excitation circuit and a large-resistance detonator excitation circuit, and the fixed addresses in the intelligent selective-sending switch are addressed to realize the transmission of control commands; the scheme has wide application range and effectively improves the field work efficiency and the operation stability. However, the following disadvantages still exist: 1. the wiring is complex, and the large-resistance detonator and the magnetoelectric detonator need to be divided into two output wires; 2. part of selective firing switches can only detonate single type detonators; 3. the type of detonator needs to be distinguished by field workers, and the probability of error is introduced.

Disclosure of Invention

The invention aims to provide a self-adaptive intelligent selective firing switch for detonating an underground perforating detonator aiming at the defects of the prior art. The self-adaptive intelligent selective-transmitting switch has an independent fixed address and comprises a temperature sensor, a power supply voltage acquisition circuit, a downward power supply driving circuit, a detonator excitation circuit, a detonator type identification module and an output type selection switch, wherein the detonator type identification module and the output type selection switch are arranged between a microprocessor and an output port; the intelligent selective-sending switch has an independent fixed address, can be conducted step by step to form a multi-stage selective-sending switch, is provided with an independent detonator type identification module on each stage of selective-sending switch, and completes the communication work of an output line and a corresponding detonator excitation circuit according to an identification result; therefore, on the premise of improving the application range of the selective switch, the field working efficiency and the operation stability, the self-adaptive control of various detonators is realized, the wiring mode is simplified, and various defects caused by manual selection, such as error rate, high cost and potential safety hazards, are effectively overcome.

In order to achieve the above object, the present invention provides an adaptive intelligent selective firing switch for detonating a downhole perforating detonator, comprising: the device comprises an input ground terminal GND9, a power supply voltage input terminal VCC10, a communication transmitting unit 11, a power management module 17, a microprocessor 18, a communication receiving unit 19, a temperature sensor 23, a power supply voltage acquisition circuit 24, a triode 25, a downward power supply driving circuit 26, a magnetoelectric detonator excitation driving circuit 27, a large-resistance detonator excitation driving circuit 32, an output ground terminal GND36 and a downward power supply interface 37; it is characterized by also comprising a detonator type identification module 38 and an output type selection switch 39 which are arranged between the microprocessor 18 and the output port;

the magnetoelectric detonator excitation driving circuit 27 consists of a frequency generator 30, a second power driving circuit 28, a first ignition output terminal 29 and a first ignition voltage acquisition circuit 31, wherein the input of the second power driving circuit 28 is connected with the output end of the frequency generator 30, and the output of the second power driving circuit is connected with the input of the first ignition output terminal 29; the large-resistance detonator excitation driving circuit 32 consists of a third power driving circuit 33, a second ignition output terminal 34 and a second ignition voltage acquisition circuit 35, wherein the output of the third power driving circuit 33 is connected with the input of the second ignition output terminal 34; the first ignition output terminal 29 and the second ignition output terminal 34 are both connected to a detonator type identification module 38 and an output port for connecting a detonator 40 in a disconnectable manner through an output type selection switch 39;

the detonator type identification module 38 is used for identifying the specific type of the detonator 40;

and the output type selection switch 39 is used for connecting the output line with a detonator excitation circuit of a corresponding type according to the identification result of the detonator type identification module 38, namely controlling and communicating the first ignition output terminal 29 or the second ignition output terminal 34.

Further, the communication sending unit 11 and the communication receiving unit 19 both process signals in a modulation and demodulation manner; the communication receiving unit 19 acquires signals from the power supply cable, and transmits the signals to the microprocessor 18 after processing; the communication sending unit 11 receives a command from the microprocessor 18 and feeds back information to the power supply cable;

the communication sending unit 11 is composed of a modulation circuit 12, a DA digital-to-analog conversion circuit 13 and an encoding circuit 14, wherein the input end of the DA digital-to-analog conversion circuit 13 is connected with the encoding circuit 14, and the output end is connected with the modulation circuit 12; the system is used for coupling information to be transmitted to a power supply cable;

the communication receiving module 19 is composed of a demodulation circuit 20, an AD/d conversion circuit 21, and a decoding and decoding circuit 22, wherein the input end of the AD/d conversion circuit 21 is connected to the demodulation circuit 20, and the output end is connected to the decoding and decoding circuit 22; the system is used for demodulating, sampling and translating the electric signals on the power supply cable into command information.

Further, the first ignition voltage acquisition circuit 31 is connected between the first ignition output terminal 29 and the microprocessor 18, and the second ignition voltage acquisition circuit 35 is connected between the second ignition output terminal 34 and the microprocessor 18; are used for feeding back the acquired voltage information through the microprocessor 18.

Further, the second ignition voltage collecting circuit 35 is connected between the second ignition output terminal 34 and the microprocessor 18, and is used for feeding back the collected voltage information through the microprocessor 18.

Further, the temperature sensor 23 is connected to the microprocessor 18, and is used for collecting temperature data and transmitting the temperature data to the microprocessor in real time.

Further, the identification result of the detonator type identification module 38 is a magnetoelectric type detonator or a large-resistance type detonator.

The above-mentioned connecting the output line with the detonator excitation circuit of the corresponding type according to the recognition result of the detonator type recognition module 38 specifically includes: if the identification result is that the detonator is a magnetoelectric detonator, the output type selection switch 39 is controlled to communicate the output line with the first ignition output terminal 29, the output amplitude is amplified through the magnetoelectric detonator excitation driving circuit 27, and the magnetoelectric detonator is excited; if the result of the identification is a large-resistance type detonator, the output type selection switch 39 is controlled to connect the output line to the second ignition output terminal 34, and a driving current for exciting the detonator is generated by the large-resistance detonator excitation driving circuit 32, so that the large-resistance detonator is excited.

Further, the detonator 40 is located outside the self-adaptive intelligent selective firing switch and comprises a magnetoelectric detonator/magnetoelectric igniter and a large-resistance detonator/large-resistance igniter.

Compared with the prior art, the invention has the following advantages:

firstly, the self-adaptive intelligent selective-sending switch is connected with the detonators of multiple types through the independent output type selection switch, so that the condition that the detonators of different types are respectively connected through a plurality of output lines is avoided, and the wiring mode is effectively simplified;

secondly, the type identification module is arranged in the circuit, so that the type of the detonator can be identified, the output line is connected with the excitation circuit of the type corresponding to the detonator to be excited by controlling the output type selection switch, the self-adaptive control of various types of detonators is realized, and the error rate and high cost caused by manual differentiation are avoided;

secondly, because the self-adaptive intelligent selective-sending switch has independent fixed addresses, the self-adaptive intelligent selective-sending switch is connected with each other in a step-by-step conduction mode to form a multi-stage selective-sending switch, each stage of selective-sending switch is provided with an independent detonator type identification circuit, the detonator is controlled by the independent output type selective switch, and the fixed addresses in the intelligent selective-sending switch are addressed to realize the transmission of control commands, thereby expanding the application range and effectively improving the field work efficiency and the operation stability.

Drawings

FIG. 1 is a block circuit diagram of the present invention;

FIG. 2 is a schematic view of the connection of the present invention in a monoblock perforating gun string;

fig. 3 is a schematic view of the working process of the present invention.

Detailed Description

The invention is further described below with reference to the accompanying drawings.

Referring to fig. 1, a circuit block diagram of the switch of the present invention describes a specific structure of an adaptive intelligent selective switch for detonation of a downhole perforating detonator, which is provided by the present invention:

the intelligent selective-sending switch comprises an input ground terminal GND9, a power supply voltage input terminal VCC10, a communication sending unit 11, a power supply management module 17, a microprocessor 18, a communication receiving unit 19, a temperature sensor 23, a power supply voltage acquisition circuit 24, a triode 25, a downward power supply driving circuit 26, a magnetoelectric detonator excitation driving circuit 27, a large-resistance detonator excitation driving circuit 32, an output ground terminal GND36 and a downward power supply interface 37; it is characterized by also comprising a detonator type identification module 38 and an output type selection switch 39 which are arranged between the microprocessor 18 and the output port;

the magnetoelectric detonator excitation driving circuit 27 consists of a frequency generator 30, a second power driving circuit 28, a first ignition output terminal 29 and a first ignition voltage acquisition circuit 31, wherein the input of the second power driving circuit 28 is connected with the output end of the frequency generator 30, and the output of the second power driving circuit is connected with the input of the first ignition output terminal 29; the large-resistance detonator excitation driving circuit 32 consists of a third power driving circuit 33, a second ignition output terminal 34 and a second ignition voltage acquisition circuit 35, wherein the output of the third power driving circuit 33 is connected with the input of the second ignition output terminal 34; the first ignition output terminal 29 and the second ignition output terminal 34 are both connected to the detonator type identification module 38 and an output port in a disconnectable manner through an output type selection switch 39, and the output port is used for connecting a detonator 40, such as a magnetoelectric detonator/magnetoelectric igniter, a high-resistance detonator/high-resistance igniter.

the detonator 40 is positioned outside the self-adaptive intelligent selective firing switch, and when the detonator is used, the detonator and the selective firing switch are placed into the perforating gun together;

and the output type selection switch 39 is used for connecting the output line with a detonator excitation circuit of a corresponding type according to the identification result of the detonator type identification module 38, namely controlling and communicating the first ignition output terminal 29 or the second ignition output terminal 34. Here, the recognition result of the detonator type recognition module 38 is: a magnetoelectric type detonator or a high-resistance type detonator. According to the recognition result of the detonator type recognition module 38, the output line is connected with the detonator excitation circuit of the corresponding type, specifically: if the identification result is that the detonator is a magnetoelectric detonator, the output type selection switch 39 is controlled to communicate the output line with the first ignition output terminal 29, the output amplitude is amplified through the magnetoelectric detonator excitation driving circuit 27, and the magnetoelectric detonator is excited; if the result of the identification is a large-resistance type detonator, the output type selection switch 39 is controlled to connect the output line to the second ignition output terminal 34, and a driving current for exciting the detonator is generated by the large-resistance detonator excitation driving circuit 32, so that the large-resistance detonator is excited.

In addition, the invention is applicable to detonators for perforation operation in most domestic areas. The detonator type in the technical scheme can be other detonators used for perforating operation besides a magnetoelectric detonator and a large-resistance detonator, for example, high-voltage pulse detonators are also used in some foreign blocks, if the detonator type is introduced, voltage doubling voltage can be added on the basis of the current self-adaptive intelligent switch product, and a high-voltage pulse detonator identification module is introduced, so that the detonator type can be compatible with the high-voltage pulse detonators, and the high-voltage pulse detonators can be excited. In the same way, the new type of detonator is continuously added, and the invention can still complete the operation task of automatic identification and excitation by changing part of the circuit module.

The communication transmitting unit 11 and the communication receiving unit 19 both process the signals in a modulation and demodulation manner; the communication receiving unit 19 acquires signals from the power supply cable, and transmits the signals to the microprocessor 18 after processing; the communication sending unit 11 receives a command from the microprocessor 18 and feeds back information to the power supply cable;

The intelligent selective-transmitting switch of the invention receives the signal coupled to the power supply voltage input end VCC10 through the communication receiving unit 19 inside the intelligent selective-transmitting switch, demodulates and decodes the signal, analyzes the command transmitted on the cable and transmits the command to the microprocessor 18, and the microprocessor 18 judges the command as follows:

if the command is a cascade command, the address information of the communication sending unit 11 is returned to the communication cable, and downward power supply is attempted through the triode 25;

if the command is a positioning command, returning address information carried in the command, judging whether the address of the current level is consistent with the address carried in the command, if so, positioning the current level, and if not, issuing the information to the next level;

if the command is an ignition command, the magnetoelectric detonator excitation driving circuit 27 and the large-resistance detonator excitation driving circuit 32 are sequentially opened, the magnetoelectric detonator connected with the output end of the magnetoelectric detonator excitation driving circuit 27 and the large-resistance detonator connected with the output end of the large-resistance detonator excitation driving circuit 32 are excited, and ignition is finished.

The first ignition voltage acquisition circuit 31 is connected between the first ignition output terminal 29 and the microprocessor 18, and the second ignition voltage acquisition circuit 35 is connected between the second ignition output terminal 34 and the microprocessor 18; are all used for feeding back the acquired voltage information through the microprocessor 18; the second ignition voltage collecting circuit 35 is connected between the second ignition output terminal 34 and the microprocessor 18, and is used for feeding back collected voltage information through the microprocessor 18.

The collected voltage is transmitted to the communication sending unit 11 through the microprocessor 18, so that the voltage is further returned to the ground control panel, and the information can be used as a judgment basis for judging whether the magnetoelectric detonator is detonated.

The temperature sensor 23 is connected to the microprocessor 18 and used for collecting temperature data and transmitting the temperature data to the microprocessor in real time.

The invention can collect parameters such as underground temperature, switch working voltage, ignition output voltage and the like, realizes single-core long-distance communication of underground cables, namely 7-15 kilometers underground bidirectional communication through the communication sending module 11 and the communication receiving module 19, and feeds underground data back to a ground system in real time.

Referring to fig. 2, the connection schematic diagram of the invention in the integral perforating gun string is that in the actual use process of the switch, a constructor installs an intelligent selecting and sending switch for each gun barrel and connects N self-adaptive intelligent selecting and sending switches step by step, and each step of selecting and sending switches is provided with an input end, a ground wire, a cascade end and a detonator excitation output end. As shown in fig. 2, the number 1 intelligent selective-sending switch 5, the number 2 intelligent selective-sending switch 6, and up to the number N intelligent selective-sending switch 7, where N is a natural number greater than or equal to 1; with the intelligent election switch of preface No. 1 with be connected to the lower extreme of logging cable 3 through other downhole equipment 4, upwards through logging cable 3 with intelligent election send control system panel 2 be connected, can use intelligent election send control system panel 2 to operate in the use, also can use PC end software 1 to operate. The selective sending switch works to realize cascade connection among a plurality of selective sending switches in a step-by-step conduction mode, namely after the Nth-stage selective sending switch is switched on, the serial number, the temperature, the fixed address and the type information of the connected detonator of the switch are fed back to the intelligent selective sending control system.

Referring to fig. 3, the working flow diagram of the invention is that PC end software is connected with a panel of a selective transmission control system through a USB, the panel couples a command message of a PC end to a logging cable, and a communication transceiver module of a selective transmission switch processes a signal in a modulation and demodulation manner to complete the work of acquiring the signal from a power supply cable and feeding back information to the power supply cable; the power supply management module provides proper voltage for the whole switch; and the communication analysis module is used for demodulating and decoding the signals after receiving the signals transmitted by the ground, analyzing the commands transmitted on the cable, transmitting the commands to the microprocessor, and judging and responding the commands by the microprocessor. If the command is judged to be a cascade command, the address information of the communication cable is returned to the communication cable through the communication sending unit, and downward power supply is tried through the triode; if the command is a positioning command, returning address information carried in the command, judging whether the address of the current level is consistent with the address carried in the command, if so, positioning the current level, and if not, issuing the information to the next level; if the command is an ignition command, the magnetoelectric detonator excitation driving circuit and the large-resistance detonator excitation driving circuit are sequentially switched on. And after the intelligent selective transmission switch receives an ignition command of the intelligent selective transmission control system, the output type selection switch is controlled according to the detonator type identified by the type identification module, and the output line is connected with the excitation circuit of the corresponding detonator type. And if the detonator is a magnetoelectric detonator: the special frequency required by the magnetoelectric detonator/magnetoelectric igniter is generated by the frequency generator, and the output amplitude is amplified by the driving circuit and is used for exciting the magnetoelectric detonator/magnetoelectric igniter; if the detonator is a large-resistance type detonator: generating a driving current for exciting the large-resistance detonator/large-resistance igniter through a large-current driving circuit to excite; thereby completing the excitation of various types of detonators/magnetoelectric igniters and completing the ignition.

The switch provided by the invention is already used in a plurality of operation areas of the Changqing oil field, and the one-time success rate of finishing the ignition work by using the switch at present is 100 percent; the accumulated number of the excitation detonators exceeds 15000 times.

The invention has not been described in detail in part of the common general knowledge of those skilled in the art.

While the invention has been particularly shown and described with reference to a preferred embodiment, it will be understood by those skilled in the art that various changes in form and detail may be made therein without departing from the spirit and scope of the invention.

Claims

1. A self-adaptive intelligent selective-firing switch for detonation of an underground perforating detonator comprises an input grounding end GND (9), a power supply voltage input end VCC (10), a communication transmitting unit (11), a power management module (17), a microprocessor (18), a communication receiving unit (19), a temperature sensor (23), a power supply voltage acquisition circuit (24), a triode (25), a downward power supply driving circuit (26), a magnetoelectric detonator excitation driving circuit (27), a large-resistance detonator excitation driving circuit (32), an output grounding end GND (36) and a downward power supply interface (37); the detonator is characterized by also comprising a detonator type identification module (38) and an output type selection switch (39), wherein the detonator type identification module and the output type selection switch are arranged between the microprocessor (18) and the output port;

the magnetoelectric detonator excitation driving circuit (27) consists of a frequency generator (30), a second power driving circuit (28), a first ignition output terminal (29) and a first ignition voltage acquisition circuit (31), wherein the input of the second power driving circuit (28) is connected with the output end of the frequency generator (30), and the output of the second power driving circuit is connected with the input of the first ignition output terminal (29); the high-resistance detonator excitation driving circuit (32) consists of a third power driving circuit (33), a second ignition output terminal (34) and a second ignition voltage acquisition circuit (35), wherein the output of the third power driving circuit (33) is connected with the input of the second ignition output terminal (34); the first ignition output terminal (29) and the second ignition output terminal (34) are both connected to a detonator type identification module (38) and an output port in a disconnectable manner through an output type selection switch (39), and the output port is used for connecting a detonator (40);

the detonator type identification module (38) is used for identifying the specific type of the detonator (40);

and the output type selection switch (39) is used for connecting the output line with a detonator excitation circuit of a corresponding type according to the identification result of the detonator type identification module (38), namely controlling and communicating the first ignition output terminal (29) or the second ignition output terminal (34).

2. The switch of claim 1, wherein: the communication sending unit (11) and the communication receiving unit (19) both adopt a modulation and demodulation mode to process signals; the communication receiving unit (19) acquires signals from the power supply cable, and transmits the signals to the microprocessor (18) after processing; the communication transmitting unit (11) receives commands from the microprocessor (18) and feeds back information to the power supply cable.

3. The switch of claim 2, wherein: the communication sending unit (11) is composed of a modulation circuit (12), a DA digital-to-analog conversion circuit (13) and a coding circuit (14), wherein the input end of the DA digital-to-analog conversion circuit (13) is connected with the coding circuit (14), and the output end of the DA digital-to-analog conversion circuit is connected with the modulation circuit (12); for coupling the information to be transmitted to the power supply cable.

4. The switch of claim 2, wherein: the communication receiving module (19) is composed of a demodulation circuit (20), an AD analog-to-digital conversion circuit (21) and a decoding circuit (22), wherein the input end of the AD analog-to-digital conversion circuit (21) is connected with the demodulation circuit (20), and the output end of the AD analog-to-digital conversion circuit is connected with the decoding circuit (22); the system is used for demodulating, sampling and translating the electric signals on the power supply cable into command information.

5. The switch of claim 1, wherein: the first ignition voltage acquisition circuit (31) is connected between the first ignition output terminal (29) and the microprocessor (18) and is used for feeding back acquired voltage information through the microprocessor (18).

6. The switch of claim 1, wherein: and the second ignition voltage acquisition circuit (35) is connected between the second ignition output terminal (34) and the microprocessor (18) and is used for feeding back acquired voltage information through the microprocessor (18).

7. The switch of claim 1, wherein: the temperature sensor (23) is connected to the microprocessor (18) and used for collecting temperature data and transmitting the temperature data to the microprocessor in real time.

8. The switch of claim 1, wherein: the identification result of the detonator type identification module (38) is a magnetoelectric type detonator or a large-resistance type detonator.

9. The switch of claim 8, wherein: the output line is connected with the detonator excitation circuit of the corresponding type according to the identification result of the detonator type identification module (38), and the method specifically comprises the following steps: if the identification result is that the detonator is a magnetoelectric detonator, controlling an output type selection switch (39) to communicate an output line with a first ignition output terminal (29), and exciting the magnetoelectric detonator by amplifying the output amplitude through a magnetoelectric detonator excitation drive circuit (27); if the result of the identification is a large-resistance detonator, the output type selection switch (39) is controlled to enable the output line and the second ignition output terminal (34) to generate a driving current for exciting the detonator through a large-resistance detonator excitation driving circuit (32), and the large-resistance detonator is excited.

10. The switch of claim 1, wherein: the detonator (40) is positioned outside the self-adaptive intelligent selective-firing switch and comprises a magnetoelectric detonator/magnetoelectric igniter and a large-resistance detonator/large-resistance igniter.