RU2509210C1 - Measurements while drilling - Google Patents

Abstract

FIELD: mining.

SUBSTANCE: system of measurements while drilling is proposed, comprising the following connected components: a module of an electric generator-pulsator, a module of an inclinometer and a module of gamma logging, including telemetering units. At the same time the specified telemetering system additionally comprises a unit of analysis and control of a switchboard and a switchboard connected to the specified modules. Besides, the inlet of the switchboard analysis and control unit is connected to the outlet of the control unit of the gamma logging module pulsations and the first inlet of the switchboard. And the outlet of the switchboard analysis and control unit is connected to the inlet of switchboard control. Besides, the second inlet of the switchboard is connected to the outlet of the inclinometer module pulsations control unit, and the outlet of the switchboard is connected to the inlet of the pulsator, installed in the module of the electric generator-pulsator.

EFFECT: increased quality of well survey due to increased reliability of information transfer from a bottomface to surface.

7 cl, 1 dwg

Description

The invention relates to drilling wells and can be used to control downhole parameters during drilling, as well as during logging during drilling.

A retrievable downhole telemetry system is known (RU 25535, publ. 10.10.2002) with a downhole tool installed inside the insert in the drill pipe string above the downhole motor, containing an electronic unit located in the casing of the downhole tool with sensors, for example, inclinometric, a transmitting device for transmitting information via electromagnetic and / or a hydraulic communication channel and a generator located below, while the generator is kinematically connected via a coupling or flexible connection to a downhole motor directly or through a mule there is a multiplier, and a pulsator of a communication channel is installed above the inclinometric sensors.

A device for logging horizontal wells (RU 2353955, published April 27, 2009) contains autonomous geophysical modules lowered into the well, interconnected into an assembly, to the upper part of which is connected a means for connecting the assembly to the drill pipe string, as well as a ground complex, including a depth gauge and a personal computer, wherein the assembly comprises gamma-ray, three-probe neutron-neutron, multi-probe electric side log, wave acoustic log, acoustic profiler, and a clinometer, while in the lower part of the assembly there is a nozzle for leaving drilling drilling fluid into the annulus during well washing, and each autonomous geophysical module contains an autonomous power supply, signal and memory conversion units. EFFECT: obtaining an effective complex of equipment for studying horizontal and deviated wellbores and, as a result, increasing the informativeness of geophysical studies of horizontal wells while reducing the accident rate of this type of work.

A device for drilling wells (WO 9816712, publ. 04.23.1998), comprising a downhole telemetry system with an electromagnetic communication channel. The downhole motor is connected to the drill bit through a drive shaft that rotates the drill bit when the drilling fluid passes under pressure. Devices that provide information for directional drilling, a modular design and include gamma radiation devices for measuring gamma ray intensity and instruments for determining the inclination and azimuth of the drill string. During operation, electromagnetic waves are transmitted, receiving antennas detect perturbed waves. The detected signals are processed in downhole circuits, which are transmitted to the control unit to the surface using a telemetry system.

A device for drilling wells (US 2005115741, publ. 02.06.2005), comprising a downhole telemetry system with an electromagnetic or hydraulic communication channel, which includes electronic components for collecting and processing well data and transmitting the processed information to the surface. The processed information can be transmitted to the surface by generating a pulse in the mud column using a valve that opens and closes to receive pulses. The downhole telemetry system also includes an electric generator, modules of gamma radiation and an inclinometer.

However, the known systems do not provide uninterrupted operation in case of loss of operability of one of the telemetry modules.

The objective of the present invention is to improve the quality of well research during drilling, including obtaining data for controlling directional drilling in real time due to more reliable transmission of information from the bottom to the surface.

The solution to this problem is achieved by the fact that the downhole telemetry system, comprising a pulsator-generator module, an inclinometer module, a gamma-ray module, interconnected in pairs through the first and second cable connections, additionally contains a switch analysis and control unit and a switch installed in the gamma module well-logging.

The pulsator electric generator module comprises an electric generator connected to a pulsator, which controls a poppet valve.

The inclinometer module contains telemetric units: the inclinometer sensor unit, the inclinometer module electronic unit, the inclinometer module power supply, the pulsation control unit of the inclinometer module, interconnected.

The gamma-ray module contains telemetric units: a gamma-ray detector unit, an electronic unit of the gamma-ray module, a gamma-ray module power supply, a pulsation control unit of the gamma-ray module, an analysis and control unit for the switch, a switch interconnected.

The inclinometer module can work both separately and together with the gamma-ray logging module.

The input of the analysis and control unit of the switch is connected to the output of the pulsation control unit of the gamma-ray module and the first input of the switch, and the output of the analysis and control unit of the switch is connected to the control input of the switch. The second input of the switch is connected to the output of the pulsation control unit of the inclinometer module through a second cable connection.

The output of the switch through the first cable connection is connected to the input of the pulsator.

For data transmission in the telemetry systems MWD (monitoring while drilling) and LWD (logging while drilling), sensors located at the lower end of the drill pipe string continuously or periodically monitor spatial parameters, and information is transmitted to the surface during drilling. The transmitted data is digitally encoded and along the column of the washing solution, physically representing a hydraulic communication channel, are transmitted in the form of pressure pulses. The hydraulic communication channel in the MWD and LWD television systems is currently the most reliable and widely used.

The invention is aimed at improving the reliability of the equipment in case of failure of one of the measuring modules, as a result of which the desired technical result is achieved to improve the quality of well research during drilling, which ultimately reduces costs and time and increases drilling efficiency.

Switching the pulsator control signal from the output of the pulsation control unit of the gamma-ray module to the output of the pulsation control unit of the inclinometer module provides a significantly higher reliability of the telemetry system as a whole, since, in the event of a failure of the gamma-ray module, only information is lost relating to the background of gamma radiation in the near-tube space, and the basic information that determines the spatial position of the layout of the bottom of the drill string (BHA) is transmitted to the top. In addition, removing gamma-ray background information from data packets frees time intervals in data packets, which additionally increases the frequency of updating inclinometric information and, ultimately, the accuracy of directional drilling. In addition, there is no need to raise the failed telesystem up to replace the failed gamma-ray logging module, which significantly reduces both time and material drilling costs.

The combination of these distinguishing features allows us to obtain a new quality of the telemetry system - increasing the reliability of the telemetry system by almost half due to the use of the inclinometer module for transmitting data upwards in case of failure of the gamma-ray logging module.

The invention is illustrated in the drawing, which schematically shows the proposed downhole telemetry system (figure 1).

The inclinometer module 1 contains an inclinometer sensor unit 2, an inclinometer module 3 electronic module, an inclinometer module 4 power supply unit, an inclinometer module pulsation control unit 5. The inclinometer module 1 can operate independently or in conjunction with a gamma-ray logging module 13. Inclinometer module 1 connected to the gamma-ray logging module 13 through a second cable connection 6 with connectors. The gamma-ray logging module 13 comprises a gamma-ray detector 7 unit, an electronic block of the gamma-ray logging module 8, a power supply unit of the gamma-ray logging module 9, a pulsation control unit of the gamma-ray logging module 10, an analysis and control unit of the switch 11, switch 12. Through the first cable connection 14 with connectors, the gamma-ray logging module 13 is connected to the pulsator-generator 17 module, which in a single structural unit contains a generator 15, which feeds the inclinometer 1 and gamma-ray logging 13, and a pulsator 16, which controls it is equipped with a poppet valve 18, which creates positive pressure pulses of the drilling fluid during reciprocating motion.

Downhole telemetry system works as follows.

When lowering the drilling tool into the borehole, the downhole tools - inclinometer module 1, gamma-ray logging module 13 and pulsator-electric generator module 17 - are connected in pairs through the first 14 and second 6 cable connections and are mounted in a protective casing capable of withstanding the high pressure of the drilling fluid generated when drilling pumps. In the process, the flow of drilling fluid passes through the guiding apparatus and the rotor of the hydraulic turbine (not shown) of the electric generator 15, which, when the rotor rotates, generates electrical voltage supplied to the modules of the inclinometer 1 and gamma-ray logging 13.

When working together, the gamma-ray logging module 13 is leading with respect to the inclinometer module 1. This means that the electronic unit of the gamma-ray logging module 8 periodically polls the electronic block of the inclinometer module 3 via the interface line and receives inclinometric information from it. At the same time, the electronic unit of the gamma-ray logging module 8 interrogates the block of the gamma-ray detector 7 and calculates the level of the gamma-ray background of the formation in the near-tube space. With a given frequency, the electronic unit of the gamma-ray logging module 8 generates data packets consisting of a set of measured inclinometry and gamma-ray logging parameters. The data packet in the form of a sequence of binary numbers from the electronic unit of the gamma-ray logging module 8 is supplied to the pulsation control unit of the gamma-ray logging module 10, from the output of which through the switch 12 is fed to the input of the pulsator 16. The pulsator 16 converts the binary sequence into reciprocating valve movements 18 . During normal operation of both the inclinometer modules 1 and gamma-ray logging 13, the analysis and control unit of the switch 11 generates a control signal of the switch 12 so that the switch 12 passes the signal pulsations from the output of the pulsation control unit of the gamma-ray logging module 10. In the event of a failure of any block of the gamma-ray logging module 13, the electronic block of the gamma-ray logging module 8 stops emitting pulsations, the analysis and control unit of the switch 11 recognizes a failure (for example, the absence of pulsations ) and generates a signal for switching switch 12. Switch 12 switches its inputs to transmit pulsation pulses from the output of the electronic unit of the inclinometer module 3. Thus, the failure of any mode block is parried gamma-ray logging 13 with a partial loss of functions, i.e. with the absence of gamma radiation parameter in the data packets. In the future, if the gamma-ray logging module 13 restores its functionality, the analysis and control unit of the switch 11, having recognized the fact of the restoration of operability, will switch the switch 12 to the passage of ripple signals from the gamma-ray logging module 13.

The application of the invention allowed to increase the reliability of the telemetry system for the formation of transmitted signals almost twice by increasing fault tolerance and using reserves of individual parts of the system.

Claims (7)

1. Downhole telemetry system comprising interconnected pulser generator module, inclinometer module, gamma ray module, including telemetry blocks, characterized in that it further comprises a switch analysis and control unit and a switch connected to these modules, while the input the analysis and control unit of the switch is connected to the output of the pulsation control unit of the gamma-ray module installed in the gamma-ray module and the first input of the switch, and the output of the analysis unit switch control coupled to the switch control input, the second input switch is connected to the output of the ripple control module inclinometer mounted inclinometer in module, and the switch output is connected to the input of the pulsator installed in the pulsator-electric module. 2. The downhole telemetry system according to claim 1, characterized in that the analysis and control unit of the switch and the switch are installed in the gamma-ray logging module. 3. Downhole telemetry system according to claim 1, characterized in that said modules are interconnected in pairs through the first and second cable connections. 4. Downhole telemetry system according to claim 1, characterized in that the inclinometer module is configured to separately or collaborate with the gamma-ray logging module. 5. The downhole telemetry system according to any one of claims 1 to 4, characterized in that the pulsator-generator module comprises an electric generator connected to a pulsator that controls a poppet valve. 6. The downhole telemetry system according to any one of claims 1 to 4, characterized in that the inclinometer module comprises interconnected block of inclinometric sensors, an electronic block of the inclinometer module, a power supply module of the inclinometer, a pulsation control unit of the inclinometer module. 7. The downhole telemetry system according to any one of claims 1 to 4, characterized in that the gamma-ray log module comprises interconnected gamma-ray detector block, an electronic block of the gamma-ray log module, a power supply unit of the gamma-ray log module, a pulsation control module gamma-ray logging, switch, switch analysis and control unit.