RU2278956C1 - Method and device for perforating equipment activation in well - Google Patents

Abstract

FIELD: oil production, particularly to activate equipment used for productive formation perforation and isolation, rock sample taking and accident elimination.

SUBSTANCE: method involves lowering perforating equipment connected to pipes in well and triggering charge initiation means by connecting above means to current source. The current source is self-contained current source located in down-hole equipment. To connect self-contained current source to initiation means corresponding command is given by discrete pipe string rotation with different angular velocities. Initiation means actuation is carried out along with predetermined depth control. Device for above method implementation comprises land-based module and down-hole module. Down-hole module comprises charge initiation means, for instance glowing filament, self-contained current source connected to initiation means, communication means, indicator, microprocessor, pressure relay, motion sensor, three electronic keys and two voltage changers. Self-contained power source is linked to input of the first voltage changer and input of the first electronic key. Outputs of the first voltage changer are connected with inputs of microprocessor power supply units, motion sensors and pressure relay. Output of motion sensor is linked to the first microprocessor input. Pressure relay output is attached to input of the first electronic key control. Output thereof is connected to input of the third electronic key through serially connected the second electronic key and the second voltage changer. Two microprocessor outputs are linked correspondingly to inputs of indicator and the third electronic key control. Output of the third electronic key is connected with initiation means input.

EFFECT: increased reliability of perforating equipment activation inside well.

2 cl, 2 dwg

Description

The invention relates to the oil and gas production and mining industry in the development, development and repair of predominantly strongly inclined and horizontal wells and is intended to launch perforated explosive equipment used in the opening of productive formations, uncoupling of formations, sampling of rocks and elimination of accidents.

A known method of initiating charges, in which an explosive circuit is mounted, including a laser, charges and an initiating path in the form of an optical fiber, through which an initiating pulse is supplied from the laser exit along the longitudinal axis of the optical fiber to detonate detonated charges by means of transmitted optical energy. The laser is located in the execution zone of the command and connected to the starting device through the laser pump path. As a path, either a logging cable or a fiber optic cable is used (RF patent No. 2107256, MKI 6 F 42 D 3/04, 1/04, F 42 C 13/02 of 08/27/97).

The disadvantage of this method is the need to use a cable, which makes it impossible to use this method for work in highly deviated and horizontal wells.

A known method of initiating charges (RF patent No. 2202097, MKI 7 F 42 B 3/113 from 06/13/2001). In this method, an explosive circuit is mounted, including a fuse with a flammable element in the form of a light source that directly contacts the initiating explosive, a pulsed LED is used as the light source, and a photosensitive explosive is used as the initiating explosive, which is directly applied to the light emitting area of the LED.

The disadvantage of this method is the difficulty of its implementation in downhole equipment, run on tubing.

A known system for initiating a charge by means of an ignition unit, used in a sectional free-flow charge for gas-hydraulic impact on a formation, consisting of a ground control panel connected through the wires of a wireline cable to an ignition unit containing power wires and an incandescent spiral. After the charge is lowered into the processing interval, the device is started by command from the ground control unit by applying a supply current to the incandescent spiral (RF patent No. 2178072, class E 21 V 43/263, 2000).

The disadvantage of this initiation system is the need for a logging cable, which causes great difficulties in application when it is necessary to deliver a large amount of combustible material to the treatment zone using a pipe string (for example, tubing pipes).

The closest in technical essence to the claimed invention are industrially used cumulative perforators PNKT1-89 and PNKT1-73, lowered on tubing (Shooting and explosive equipment. Handbook edited by L.Ya. Fridlyander, M .: Nedra, 1990, pg. 62-72).

Punchers PNKT1-89 and PNKT1-73 consist of a head with a percussion mechanism and a body with cumulative charges and detonation means. The descent of the perforators produced on tubing. To actuate the PNKT1 type perforator, after installing it in the required perforation interval and equipping the wellhead with fountain fittings, a rubber ball is thrown through the wellhead valve into the tubing string. Moving under the influence of its own weight and the fluid pumped by the pump, the ball reaches the stem seat and completely blocks the axial channel of the coupling. Under the action of increasing pressure on the rod, the safety pin is cut off, after which the rod presses on the spacer sleeve and cuts off the second pin. Moving down, the sleeve releases the balls, the drummer disengages from the body head and, under the influence of hydrostatic pressure, energetically rushes down, while the sting hammer strikes the detonator capsule, causing the triggering device to trigger. The rubber ball, pushing the rod below the side holes in the coupling, does not interfere with further fluid circulation.

The launch of the PNKT1-89 and PNKT1-73 punchers is carried out with the help of a complicated design and multi-stage action of the head with a percussion mechanism, which reduces the reliability of the operation of the punchers, and the method of starting the punch by throwing a rubber ball into the tubing string requires the use of a bulky and expensive tool to move the rubber ball inside the tubing tubing equipment for circulating well fluid. All of the above leads to a decrease in the reliability of starting the device.

The objective of the invention is to provide a reliable method of starting perforating explosive equipment in the well and a device for its implementation.

The problem is achieved by the fact that in the method of launching perforated blasting equipment in the well, which consists in lowering the equipment on pipes into the well and launching the means for initiating a charge by connecting this means to a current source, an autonomous current source is used as the current source, which is located in the downhole equipment , and to connect an autonomous current source to the initiating means, a command is set by discrete rotation of the pipe string with different angular velocities, while at the same time starting initiating CTBA monitor the passage of a predetermined.

The essence of the method lies in the fact that as a current source for supplying an incandescent spiral, the charge initiating means use an autonomous current source located in a pressure-resistant housing with a pressure switch, with a rotation sensor and with control circuits. During the descent of the device on the pipes into the processing interval, after passing a certain depth, due to the influence of hydrostatic pressure, the pressure switch is activated and generates an enable signal for the control circuit. After reaching the processing interval at the wellhead, discrete rotations of the pipe string with different angular velocities are performed. Rotation is sensed by a motion sensor that generates a useful signal when the angular speed of rotation exceeds a certain value. The control circuit, when a predetermined code coincides with discrete rotations and in the presence of a permission signal, connects an autonomous power source to the initiating means through pressure glands.

To implement the method, a device for launching a standard means of initiation in the well is proposed.

A device for launching perforating explosive equipment in a well comprises a ground unit and a well unit including a means for initiating a charge, for example, an incandescent coil. An autonomous current source connected to the initiating means, a switching device, an indicator, a microprocessor, a pressure switch, a motion sensor, a first electronic key, a second electronic key, a third electronic key, a first voltage converter, and a second voltage converter are introduced into the borehole unit the power source through the switching device is connected to the input of the first voltage converter and to the input of the first electronic switch, the outputs of the first voltage converter are connected with power inputs of the microprocessor, motion sensor and pressure switch, the output of the motion sensor is connected to the first input of the microprocessor, the output of the pressure switch is connected to the control input of the first electronic key, the output of which is connected to the input of the second electronic key, the output of which is connected to the input of the second voltage converter the output of which is connected to the input of the third electronic key, the input of the second voltage converter is connected to the output of the second electronic key, the indicator input is connected to the first micro output rotsessora, control input of the third electronic switch is coupled to the second output of the microprocessor, the output of the third electronic switch is coupled to the input means of initiation.

Figure 1 shows a structural diagram of a device for launching perforating explosive equipment in the well.

Figure 2 shows the structural diagram of the starting device for starting perforating explosive equipment in the well.

The method of starting perforating explosive equipment in the well (figure 1) is as follows.

In the initiating node 1 perforating explosive equipment 2 install the starting device 3 and lower the perforating explosive equipment into the well 4 on the tubing or drill pipe 5 in a predetermined interval. Using standard drilling equipment, for example, KTG-89 6 key, according to visual, sequential, with or without sound accompaniment, the commands issued by the command device 7 installed on the control panel of standard drilling equipment, carry out a discrete rotation of the column with a given angular speed tubing or drill pipe in one direction until the command device displays a visual and / or sound command to evacuate people to a safe distance from the mouth wells, the evacuation of people within a predetermined time - delays the supply of a given electrical impulse to start, and after a predetermined delay time, the starting device 3 launches the perforating explosive equipment in the well.

The device can be used to launch perforating explosive equipment used to open productive formations, increase well productivity, uncouple formations, take rock samples and eliminate accidents in the well.

A device that implements a method of launching perforating explosive equipment in a well includes a command device 7 (see Fig. 1) and a starting device 3 (see Fig. 1), the starting device includes (Fig. 2) placed inside a sealed pressure-resistant housing with two external pressure outputs (not shown in the figures) for connecting the starting device to the means for initiating the perforating explosive equipment, motion sensor 8 and control circuit 9, which includes an autonomous current source 10, for example, a 3.6 V d-type lithium battery SL-760 To power the starting device, a switching device 11, for example, an ESP2010 slide switch for connecting an autonomous current source to loads, a first voltage converter 12, for example, based on a MAX641 chip to generate a supply voltage for a control circuit, a first electronic switch 13, for example, based on transistor IRF7314 for supplying the connection of an autonomous current source through a switching device 11 to the input of a second electronic switch 16, a pressure switch 14, for example, based on a pressure sensor D60 with a gain circuit and normalizing the signal for controlling the first electronic switch 13, the microprocessor 15, for example, based on an ATtiny15L chip with resident software that implements the control algorithm 9, the second electronic switch 16, for example, based on the IRF7314 transistor for supplying voltage to the second converter voltage 18, indicator 17, for example, based on the KRS3216 LED to indicate the supply voltage to the control circuit 9, the second voltage converter 18, for example, based on the MAX641 chip to generate the voltage of the means for initiating the perforating and explosive equipment, the third electronic switch 19, for example, based on the transistor IRF 7343 for supplying voltage to the means for initiating the perforating and explosive equipment.

Moreover, the autonomous current source 10 through the switching device 11 is connected to the input of the first voltage converter 12 and to the input of the first electronic switch 13, the outputs of the first voltage converter 12 are connected to the power inputs of the microprocessor 15, motion sensor 8 and pressure switch 14, the output of the motion sensor 8 is connected to the first input of the microprocessor 15, the output of the pressure switch 14 is connected to the control input of the first electronic key 13, the output of which is connected to the input of the second electronic key 16, the output of which is connected to the WTO input of the second voltage converter 18, the output of which is connected to the input of the third electronic key 19, the input of the second voltage converter 18 is connected to the output of the second electronic key 16, the input of the indicator 17 is connected to the first output of the microprocessor 15, the control input of the third electronic key 19 is connected to the second output of the microprocessor 15 , the output of the third electronic key 19 is connected to two external pressure outputs (not shown in the figures). The aforementioned connections of the elements of the control circuit ensure the correct operation of the launch device of the perforated explosive equipment.

The device operates as follows.

Before installing the starting device in the initiating node of the perforating explosive equipment, the sealed pressure-resistant housing of the device is opened and then the autonomous power source 10, using the switching device 11, is connected to the first voltage converter 12 to generate a supply voltage to the control circuit. The first voltage converter 12 generates voltage to power the microprocessor 15, pressure switch 14 and motion sensor 8. After the first voltage converter is turned on, indicator 17 lights up, informing workers about the starting device. The pressure-resistant housing of the launching device is sealed, the starting device ready for operation is placed in the initiating unit of the perforating-explosive equipment and connected by electrical wires to the hermetic leads and the means of initiating the perforating-explosive equipment. When the perforating-explosive equipment is lowered into a well filled with liquid, at a given hydrostatic pressure, a pressure switch 14 is activated, which includes a first electronic switch 13, which supplies voltage through a second electronic switch 16 to a second voltage converter 18, thereby eliminating the generation of a supply voltage initiation of perforating explosive equipment on the surface. After the installation of perforating and explosive equipment in a predetermined interval of the well, a string of tubing or drill pipe is rotated by commands from the command device along with a starting device installed in the initiating unit of the perforating and explosive equipment. The motion sensor 8 senses rotation and generates useful signals, and the microprocessor 15 converts the useful signals generated by the motion sensor into a binary code, compares it with the given one and, if the codes match, can withstand the specified delay time for the given electrical impulse to start, necessary for evacuating people to a safe distance from the wellhead, and includes a second electronic switch 16 to turn on the second voltage converter 18. If the codes do not match, then the microprocessor will not turn on the second electronic the key and the starting device will not work, then to start the perforating explosive equipment in the well, it is necessary to repeat the rotation of the tubing string or drill pipe by commands from the command device. After turning on the second voltage converter, the microprocessor includes a third electronic switch 19 for supplying a given electrical impulse to the means for initiating the perforating explosive equipment and starts it.

Claims (2)

1. The method of starting perforating explosive equipment in the well, which consists in lowering the equipment on the pipes into the well and launching the means for initiating a charge by connecting this means to a current source, characterized in that an autonomous current source is used as the current source, which is located in the downhole equipment , and to connect an autonomous current source to the initiation means, a command is given by discrete rotation of the pipe string with different angular velocities, while at the start of the initiation means Ia supervise the passage of a predetermined depth. 2. A device for starting a perforating explosive equipment in a well, comprising a ground unit and a well unit including a charge initiating device, for example an incandescent spiral, characterized in that an autonomous current source connected to the initiating means, a switching device, an indicator, is introduced into the well unit microprocessor, pressure switch, motion sensor, first electronic switch, second electronic switch, third electronic switch, first voltage converter, second voltage converter, an autonomous power source through a switching device is connected to the input of the first voltage converter and to the input of the first electronic key, the outputs of the first voltage converter are connected to the microprocessor, motion sensor and pressure switch power inputs, the output of the motion sensor is connected to the first input of the microprocessor, the pressure switch output is connected to the input control of the first electronic key, the output of which is connected to the input of the second electronic key, the output of which is connected to the input of the second converter conjugation, whose output is connected to the input of the third electronic key indicator input coupled to the first output of the microprocessor, a control input of the third electronic switch is coupled to the second output of the microprocessor, the output of the third electronic switch is coupled to the input means of initiation.

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