System and method of monitoring temperature of extended objects

IPC classes for russian patent System and method of monitoring temperature of extended objects (RU 2459954):

G01K7/14 - Arrangements for modifying the output characteristic, e.g. linearising

E21B47/12 - Means for transmitting measuring-signals or control signals from the well to the surface, or from the surface to the well, e.g. for logging while drilling

Another patents in same IPC classes:

Electronic temperature sensor / 2058019

The invention relates to thermometry, namely to electronic devices temperature measurement and can be used in measurement technology and automation

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Downlink based on pumping noise / 2441982

FIELD: drilling operation.

SUBSTANCE: invention belongs to the clarification of the fact, when the drilling was stopped within the drilling operation. The method of such a clarification includes the observation of the first sensor signal within the first chosen time interval, observation of the second sensor signal within the second chosen time interval and analysis of the noise level in order to specify whether the noise had changed in the course of the second signal.

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15 cl, 5 dwg

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Horizontal well logging jet plant / 2252339

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According to proposed method jet pump with stepped through channel in its housing and packer with through channel and complex logging device are lowered into well on tubing string. Logging device is installed under packer on tubing string. Perforated section is made on tubing string from side of its lower end. In process of lowering, using logging device, background values of physical parameters of producing formations are recorded, and then packer is released. Packer is installed higher than producing formations under surveying, and complex logging device is installed in zone of producing formations. Then depression insert is installed in stepped through channel of jet pump housing to separate tubing string, and working liquid medium is fed into nozzle of jet pump, thus building different value depressions in underpacker space of well. At each value of depression, well production rate is measured and then, with jet pump operating, complex logging device is moved along producing formations by displacing tubing string without depacking of packer and geophysical parameters of producing formations are recorded. After completion of surveying, depacking of packer and lifting of tubing string with jet pump and logging device to surface is done.

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Method comes to mounting the following device onto tubing string: pump with through channel, packer and liner with intake funnel, lowering the assembly into well, releasing the packer and creating required drawdown in underpacker zone by pumping liquid medium out of underpacker zone by jet pump. Assembly is furnished additionally with unit for disconnecting and connecting tubing string, and valve unit with seat for mounting check valve, and then tubing string is assembled in definite sequence. After these operation, investigation, testing and completion of well are carried out. Then well is set in operation.

Ejector multifunctional formation tester for testing and completion of horizontal wells / 2256102

Proposed formation tester contains jet pump, unit for connecting and disconnecting tubing string, valve unit with seat for valve insert with check valve, packer and liner with intake funnel, all mounted on tubing string from top to bottom. Jet pump housing accommodates coaxially installed active nozzle and mixing chamber, and channels are made to deliver active medium, pumped out of well and stepped through channel with seat between steps. Possibility is provided for in-turn mounting of sealing unit and interlock insert with through channel which are arranged on flexible smooth pipe higher than tip for connecting self-contained logging complex and insert for recording pressure built-up curves I underpacker space of well under which self-contained instruments are installed for recording pressure, temperature and other physical parameters of well and forming fluids. Invention provides intensification of investigation, testing and preparation of wells, mainly, horizontal and high curvature wells, optimization of operation of jet pump used together with self-contained logging complex and other functional insets for investigation of producing formation.

Method of operation of horizontal well ejector multifunctional formation tester / 2256103

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Horizontal well ejector multifunctional formation tester / 2256104

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FIELD: information technology.

SUBSTANCE: system for monitoring temperature of extended objects has temperature sensors, a means of collecting data coming from the extended object, a means of transmitting data, a computer for assessing and collecting data, lying away from the extended object and meant for receiving and assessing data. According to the invention, the system for monitoring temperature of extended objects further includes an Ethernet and the Internet, a network hub, temperature sensors, each lying in a separate protective housing and fitted with an integrated interface, connected to each other by a flexible cable and forming m thermistor chains with n_m temperature sensors in each.

EFFECT: high accuracy of measurement and reliability, simple system for monitoring temperature of extended objects, wider field of use.

The invention relates to systems and methods for monitoring temperatures of extended objects, in particular in the various wells in the ground, including frozen, frozen and thawing soils, in construction, for any complex nonlinear objects, as well as in tanks for non-aggressive liquids.

A known system for centralized monitoring and control equipment remote objects [1], containing the sensors of the objects, control devices, remote control and display information on the object, actuators, remote centralized monitoring, containing a computer survey, collection and processing of information, as well as devices receive and transmit messages to the remote centralized monitoring, containing information network. Control devices it is designed as controllers of survey sensors, devices, sending and receiving messages to the remote centralized monitoring contain interface converters, one of which is installed on each object and associated with the remote control and display information of that object, and another transducer is installed on the remote centralized monitoring and is connected directly with computer survey, collection and processing of information provided by the display device and the management objects.

The disadvantages of the known monitoring system are its complexity, high cost and small reliability.

A device for monitoring temperature in an extended object [2]containing the probe, consisting of consecutive temperature sensors, placed in a protective casing of small diameter, managing the microcontroller, the signal Converter, designed for converting signals from the above-mentioned temperature sensors in the form convenient for the control of the microcontroller, non-volatile memory, real time clock, solver, performing data analysis and identification of hazardous temperature fields of the extended object, block define the initial settings, built-in power supply, ensure the device is in offline mode when the ambient temperature -50 to +70°C, and the data interface.

The disadvantages of the known device temperature monitoring are:

- great heat of reaction due to the presence of polymer thick-walled shell, which is a probe;

- narrow scope;

low tightness Thermopolis;

- the complexity of the device temperature monitoring;

low reliability.

The closest in technical is some essence of the claimed invention is a system for centralized monitoring and control of engineering equipment remote objects [3], containing the sensors of the objects, the control apparatus and remote control and display information on the object, the remote centralized monitoring, containing a computer survey, collection and processing of information, as well as devices receive and transmit messages to the remote centralized monitoring, containing information network.

The downside of it is unreliable and crashes when there are multiple objects, a significant response time and execution control signals, the complexity of the device.

Closest to the proposed method of monitoring the temperature of extended objects is a method of monitoring supply unit [4], consisting in the installation of telemetric temperature sensors at selected points of the object, measuring the temperature and generating derivative processes during a representative period of time, processing and objectification of recorded information using a computer. As telemetric temperature sensors use electronic Thermochron sensors drives, programming them, sync start, record the temperature and time dependences, using the fast Fourier transform are specified temperature-time dependence as a function of frequency, assess relationships of the spectrum is lnyh generating capacity and derived temperature processes, about the effectiveness of thermal processes are judged according to the magnitude relationship of the integral capacity of the temperature fluctuations in the spectra of the two pairs of the selected temperature related processes.

The disadvantage of the prototype method is the complexity of the action, lack of responsiveness, reliability, and the reliability of determination of temperature.

The objective of the invention is the improvement of measurement accuracy and reliability, simplification of the proposed system temperature monitoring of extended objects, expanding the scope of its application.

This object is achieved in that the system temperature monitoring of extended objects containing temperature sensors, a means of collecting data from the extended object, the means for transferring data, the computer assessment and information gathering that is located remotely relative to the extended object and designed to receive and evaluate data according to the invention in a system for monitoring temperatures of extended objects have been added to the Ethernet network and Internet, network hub, temperature sensors, each of which is accommodated in a separate housing and is equipped with an integrated interface, connected between a flexible cable and form m termokos with n_mthe number of temperature sensors in each, the data collection tool made in the form of a counter is llera temperature sensors, performing functions of control and information display, directly supporting environment Ethernet and Internet and consists of a micro controller, module, power management, real-time clock, indicator module connected to an Ethernet network, a non-volatile memory, connectors for termokos and to an Ethernet network, each of termokos equipped with a controller, temperature sensors, a means of data transfer is executed in the form of a network hub and the receiving / transmitting device, and the outputs of each termokos connected to the connector for termokos controller, connector for Ethernet network, each controller is connected via Ethernet to the input hub, an output of which is connected with by using a network cable or transceiver device via the Internet with your computer evaluation and data collection.

This object is achieved by a method of monitoring the temperature of extended objects, which consists in setting the programmed temperature sensors in an extended objects, measuring temperature, receiving and evaluating data using computer assessment and information gathering, according to the invention using the controller to calibrate the temperature sensors are placed in series and forming termokos, write them in the calibration coefficients, stitch them to the Indus the individual designations, using temperature sensors convert the electrical analog signals received from the sensors, into digital signals, with integrated temperature sensors interface transmit signals to the controller performing control functions, display information, the transmission of digital signals over Ethernet in network hub, combining controllers, as well as through a network hub transfer digital signals through the Internet or wirelessly with the transceiver device in the computer assessment and data collection.

Figure 1 presents the scheme of the proposed system temperature monitoring of extended objects containing temperature sensors 1, forming termokos 2 and connected to the controller 3, which on an Ethernet network connected to the network hub 4, which is connected via network cable or transceiver device 5 via the Internet with the computer assessment and information gathering 6. Figure 2 presents the design of the controller 3, which contains the connector 7 for termokos 2, the connector 8 Ethernet module connection 9 to an Ethernet network, the indicator 10, the control buttons 11, the microcontroller 12, a nonvolatile memory 13, the real-time clock 14, the control module power supply 15, a battery 16. Module power management 15 conversions is t the voltage of the battery 16 in a stabilized voltage of 5 V to power all the nodes of the controller 3, and plug termokos 2. The main task of the microcontroller 12 is in communication with temperature sensors 1 termokos 2. The microcontroller 12 software implemented digital data transmission Protocol over a single-wire communication line 1-Wire. The microcontroller 12 periodically scans termokos 2 to measure its electrical capacity to adjust delays and erosion fronts digital signals, resulting in long lines. Due to this it is possible to increase the maximum length of the communication line (termokos) up to 100-150 m Microcontroller 12 controls the remaining nodes in the controller 3. The indicator 10 will display the following information:

- the serial number of termokos 2;

- the number of temperature sensors 1 in thermocole 2 and the distance to them;

- the temperature of each temperature sensor 1;

- voltage battery 16;

parameters and controller settings 3;

- the current time.

Using the control buttons 11 is turning on / off controller 3, the reading of the temperature sensors 1 termokos 2, change the settings of the controller 3. Button memory (not shown) is used to save the current measurement results from all the temperature sensors 1 termokos 2 in the nonvolatile memory 13. Non-volatile memory 13 can store up to 1600 measurements. View the contents in the nonvolatile memory 13 can be performed both on the indicator 10 of the controller 3, and the computer assessment and information gathering 6 in the form of a table or graph. Using the real-time clock 14 is determined by recording the results of measurements in non-volatile memory 13. The plug 9 to an Ethernet network performs conversion of data from the microcontroller 12 in the Ethernet format for subsequent data transmission over networks that support the Ethernet Protocol.

The proposed system temperature monitoring of extended objects is as follows. The claimed system temperature monitoring carried out in automatic mode temperature measurement of extended objects at different depths with a certain step using descended into them termokos 2, as well as the analysis of the temperature distribution along the object, which is performed by the controller 3 in order to identify emergency object situations. As extended objects can be any of the well in various soils, including frozen, freezing and thawing, in construction, for any complex nonlinear objects, as well as in tanks for non-aggressive liquids.

Temperature sensors 1 measure temperature, transfer the analog signal to a digital signal and using integrated temperatureduring 1 interface 1-Wire transmit the measurement results to the controller 3. The controller 3 is the initial programming of the temperature sensor 1 and a write calibration coefficients, which allow to increase the accuracy of the measurements. The controller 3 is also powered termokos 2. The controller 3 may perform the following procedures with temperature sensors 1 termokos 2:

1. Calibration of temperature sensors 1 termokos 2.

When calibrating the determined calibration coefficients to the readings of the temperature sensors 1 termokos 2. Then, the controller 3 writes the calibration coefficients directly in each temperature sensor 1 termokos 2.

2. Firmware individually identify each temperature sensor 1 termokos 2.

Using the controller 3 assigns each temperature sensor 1 termokos 2 individual designation. This designation in the future is read from the temperature sensor 1 and is shown together with the measurement results of the sensor.

The controller 3 is programmed in such a way that does not require a Converter interfaces, as it directly supports the environment of Ethernet and the Internet. Each controller 3 via an Ethernet network connects to the network hub 4, which combines the 3 controllers temperature sensors 1 in a single network and makes it possible to transfer data to the Internet. In the case of the EU and the wiring is difficult, there are options for data transmission from the hub 4 via the receiving / transmitting device 5, which provides a wireless access point to the Internet, allowing users to transfer data at a distance. Wireless access point can be realized in several ways, for example, with network operators, using a standard wireless interface, using satellite communication.

The presence of the receiving / transmitting device 4 allows you to have such advantages as:

- no long lines for data transmission over long distances;

- the battery monitoring system.

The advantages of the proposed system temperature monitoring of extended objects are that:

all temperature sensors 1 are connected in parallel to a single cable, and thus is not required to bring individual cable for each temperature sensor 1;

controllers 3 temperature sensors 1 can directly support the environment Ethernet and Internet;

- the system temperature monitoring of extended objects includes software for computer assessment and information gathering 6;

- the proposed system temperature monitoring of extended objects is significantly smaller and easier known systems;

to create a monitoring system temperature p is otogenic objects require only standard network equipment, and does not require specially trained personnel to connect to the Internet.

Sources of information

1. Patent # 82361, G08B 25/01, publ. 2008

2. Patent # 75692, G01K 7/14, publ. 2008

3. Patent No. 2263971, G08B 25/01, publ. 2003

4. Patent No. 2232352, F24D 19/10, publ. 2004

1. Monitoring system temperature extended objects containing temperature sensors, a means of collecting data from the extended object, the means for transferring data, the computer assessment and information gathering that is located remotely relative to the extended object and designed to receive and evaluate data, characterized in that the monitoring system of temperature of extended objects have been added to the Ethernet network and Internet, network hub, temperature sensors, each of which is accommodated in a separate housing and is equipped with an integrated interface, connected between a flexible cable and form m termokos with n_mthe number of temperature sensors in each, the data collection tool is made in the form of controller, temperature sensors, performing functions of control and information display, directly supporting environment Ethernet and Internet, and consists of a micro controller, module, power management, real-time clock, indicator module connected to an Ethernet network, a non-volatile memory and, connectors for termokos and to an Ethernet network, each of termokos equipped with a controller, temperature sensors, a means of data transfer is executed in the form of a network hub and the receiving / transmitting device, and the outputs of each termokos connected to the connector for termokos controller, connector for Ethernet network, each controller is connected via Ethernet to the input hub, an output of which is connected with a network cable or transceiver device via the Internet with your computer evaluation and data collection.

2. The method of temperature monitoring of extended objects, which consists in setting the programmed temperature sensors in an extended objects, measuring temperature, receiving and evaluating data using a computer, evaluate, and collect information, wherein using the controller to calibrate the temperature sensors are placed in series and forming termokos, write them in the calibration coefficients, stitch their individual designation, temperature sensors convert the electrical analog signals received from the sensors, into digital signals, with integrated temperature sensors interface transmit signals to the controller performing control functions, display inform the tion, the transmission of digital signals over Ethernet in network hub, combining controllers, as well as through a network hub transfer digital signals through the Internet or wirelessly with the transceiver device in the computer assessment and information gathering.