RU62984U1 - COMPLEX FOR MONITORING AND MEASURING PARAMETERS OF LIFTING OPERATIONS - Google Patents

Abstract

The complex for monitoring and measuring the parameters of hoisting operations includes a device 1 for recording and processing data, a unit 2 for measuring depth, a unit 3 for measuring the tension force of the cable, a reader 4 for magnetic marks, connecting cables. The device 1 contains an analog-to-digital converter, a unit for setting the limit values of the monitored parameters, a light and sound signaling unit, an indication unit, calibration and portable memory units, an intrinsically safe unit, and a display panel. Block 2 has a gear for engagement with the gear of the lower roller 12 of the block balance, and on the cover of the block 2 housing there are connectors for connecting the cable tension measuring unit 3, magnetic reader 4 and a connector 15 for connecting to the terminal 5 of the data recording and processing device 1. Block 3 measuring the tension force of the cable consists of a strain gauge bridge and a standardizing instrumental amplifier. The reader 4 of the magnetic marks is made in the form of a sealed cylindrical container, in which a sensing element is placed that senses an external magnetic field and converts it into voltage, an instrumental amplifier and a voltage stabilizer. The lower roller 12 of the block balance is attached by the cheeks 13 to the wellhead by means of a bracket. The cheeks 13 are used as a holding mechanism for the cable tension measuring unit 3, and the guides 14 of the cheeks 13 are used as the holding mechanism of the depth measuring unit 2. The reader 4 of the magnetic marks is mounted on a board fixed at the wellhead at a distance of 30-80 mm from the descent cable with the applied magnetic marks. The placement of the measuring units, including the magnetic mark reader, directly at the mouth of the well under study made it possible to ensure the accuracy of measuring the well parameters and ease of operation. 2 ill.

Description

The utility model relates to the oil and gas industry, and is intended for automated control, measurement and recording of parameters of hoisting operations in the well.

A device for measuring the length of a cable is known, comprising a measuring roller, a converter of the angle of rotation of the measuring roller with an adjustable conversion coefficient, a control unit, a recorder and a counter of magnetic marks applied to the cable. A selsyn - sensor is installed on the measuring roller, electrically connected to the selsyn - receiver, the axis of which is rigidly connected to the pulley of the converter during its mechanical design. In the electronic version of the converter, a pulse sensor is connected to the axis of the sync-receiver, consisting of a disk with slots, a light source installed on one side of the disk and a photodiode installed on the other side of the disk (AS USSR No. 1335682, Mcl ⁴ E21B 47/00 publ. 07.09.87).

The closest set of essential features to the claimed technical solution is a device for measuring the depth of the descent of the object during tripping operations in the well, containing a winch with a drum on which is located a flexible organ, amplifier, power supply, a unit for measuring displacement and tension force of a flexible organ, controller, analog-to-digital converter, unit for setting limit values of monitored parameters, light and sound signaling unit, display unit, sensor nonlinearity correction unit Single measuring tensile force of the flexible body, calibration memory unit, a portable memory unit, intrinsically safe unit and the board holding mechanism configured as a guide, one end of which is movably connected with the winch, the other end is rigidly connected with the measuring unit

movement and tension forces of a flexible organ, which can be made in the form of movable rollers, at least three, placed on a movable flexible organ in the place of its bend, or in the form of an inductive sensor or in the form of an optoelectronic sensor, and the portable memory unit is made in the form of a remote device , communication with which is carried out using a wire line or a radio channel (RF patent No. 2168624, IPC721B 47/04, publ. 10.06.01).

The disadvantages of the known technical solutions are the lack of accuracy in measuring the parameters of the well and inconvenience during operation.

The task was set: to increase the accuracy of measuring the parameters of the well and to ensure ease of use.

The problem is solved due to the fact that the complex for monitoring and measuring the parameters of hoisting operations, containing a device for recording and processing data associated with measuring units of depth and tension force of the cable, mounted on a holding mechanism, and having an analog-to-digital converter, a unit for setting limit values of monitored parameters, light and sound signaling unit, indication unit, calibration and portable memory units, intrinsically safe unit and display, additionally contains a ma tags associated with the data recording and processing device, the cheeks of the lower balance block roller and their guides are used as the holding mechanism of the cable tension measuring unit and depth measuring unit, respectively, while the depth measuring unit has a gear for engaging with the lower roller gear and on the housing cover of the indicated block there are connectors for connecting the cable tension unit, magnetic tag reader and data recording and processing device, in addition, the tension measuring unit eniya cable consists of a strain bridge and normalizing the instrumentation amplifier, and a reader of magnetic marks formed in the form of a sealed cylindrical container, which houses the sensor, sensing the external magnetic field and converts it into

voltage, instrumentation amplifier and voltage stabilizer.

The presence in the reader complex of magnetic marks, made in the form of a sealed cylindrical container, in which a sensing element that senses an external magnetic field is placed, and converts it into voltage, an instrumental amplifier and a voltage stabilizer connected with the data recording and processing device, allows automatic correction depth readings by magnetic marks, which increases the accuracy of measuring well parameters.

Using as a holding mechanism for the unit for measuring the tension force of the cable the cheeks of the lower roller of the balance block, and for the measuring unit of depth, the guiding cheeks of the lower roller of the balance block, as well as the presence in the measuring unit of the depth of the gear that engages with the gear of the lower roller and placement on the housing cover of the specified block of the connector for connecting the cable tension unit, consisting of a strain gauge bridge and a standardizing instrument amplifier, a connector for connecting a magnetic tag reader and p zema connection registration device and data processing, possible to place the measuring units directly at the mouth of the well researched and thereby provide convenience in use.

The analysis of the prior art, including a search by patent and scientific and technical sources of information, made it possible to establish that an analogue, characterized by features identical to all the essential features of the claimed technical solution, was not found. Based on the foregoing, we can conclude that the claimed technical solution meets the criterion of "novelty."

The claimed technical solution is illustrated by the drawings:

figure 1 is a structural diagram of a complex for monitoring and measuring parameters of hoisting operations;

figure 2 - complex for monitoring and measuring the parameters of hoisting operations, General view.

The complex for monitoring and measuring the parameters of hoisting operations includes a device 1 for recording and processing data, a unit 2 for measuring depth, a unit 3 for measuring the cable tension force, a reader 4 for magnetic marks, and connecting cables.

The device 1 contains an analog-to-digital converter, a unit for setting the limit values of the monitored parameters, a light and sound signaling unit, an indication unit, calibration and portable memory units, an intrinsically safe unit, and a display panel. On the back wall of the device 1 housing, there are connector 5 for connecting blocks 2, 3 and 4, connector 6 for emergency output, connector 7 for connecting loggers and connector 8 for power supply, and on the front panel of device 1 there are three-line indicator 9 with six LEDs, a switch power, connector 10 for communication with a computer, and three buttons 11 for setting the operating modes of the counter.

The depth measurement unit 2 has a built-in power supply voltage regulator microprocessor control and operates on the principle of measuring discrete angular displacement. Block 2 has a gear for engagement with the gear of the lower roller 12 of the block balance, having cheeks 13 with guides 14. On the cover of the block 2 housing there are connectors for connecting the cable tension measuring unit 3, magnetic reader 4 and a connector 15 for connecting to the device connector 5 1 registration and data processing.

Block 3 measuring the tension force of the cable consists of a strain gauge bridge and a standardizing instrumental amplifier. The operation of block 3 is based on the principle of measuring the result of vector addition of forces in the branches of a logging cable going into the well and to the winch. When a load appears on the logging cable, forces arise on the jaw 13, which cause deformation of the strain gauge bridge elements, imbalance of the bridge. The unbalance voltage is supplied to the input of the instrument amplifier,

whose output signal is proportional to the applied force. This signal is transmitted through the connecting cable to the device 1, is processed and transmitted to the data logging system of the logging station.

The magnetic tag reader 4 is made in the form of a sealed cylindrical container, in which a sensing element is placed that senses an external magnetic field and converts it into voltage, an instrumental amplifier and a voltage stabilizer. The reader 4 is based on the principle of the occurrence of an EMF in a semiconductor located in a magnetic field.

The lower roller 12 of the block balance is attached by the cheeks 13 to the wellhead by means of a bracket. The cheeks 13 are used as a holding mechanism for the cable tension measuring unit 3, and the guides 14 of the cheeks 13 are used as the holding mechanism of the depth measuring unit 2. The reader 4 of the magnetic marks is mounted on a board fixed at the wellhead at a distance of 30-80 mm from the descent cable with the applied magnetic marks.

The inventive complex operates as follows.

Before starting the lifting operations to study the parameters of the well, blocks 2 and 3 are mounted on the lower roller of the block balance 12 mounted on the wellhead, and a reader 4 is installed on the board fixed on the wellhead 4. The connector 15 of the depth measuring unit 2 is connected to the connector using a cable 5 devices 1. Check the correctness of all settings and settings and, if necessary, adjust them. The device 1 receives incremental pulses from block 2 along with the rotation direction signal and, in accordance with the increment sign programmed by the user, calculates the displacement of the geophysical cable, taking into account the diameters of the gears, the gear transmission module and the number of pulses per one revolution of block 2. Current value (depth) is formatted and displayed on the device 1. At the same time, the current position is compared with the values of the lower and upper limit position,

specified by users. Upon reaching the lower limit of the depth, if the movement continues, the device 1 beeps, warning the operator that the specified depth has already been passed. During the rise, 100 m to the upper limit position, the device 1 also gives a warning buzzer, and when it reaches the set level, it gives a signal to block the rise and an alarm buzzer. If depth recording is enabled, instrument 1 writes the current depth value to the Flash memory at time intervals specified by the user. During movement, the device 1 calculates the instantaneous speed of movement and displays the value of m / hour or km / h. During movement, instrument 1 transmits “weighted” movement pulses (increment or decrement) to the geophysical logger, 1 cm or 10 cm in dimension, depending on the parameter specified by the user. From the keyboard of the device 1, the user can set the zero depth reading, as well as set a preliminary (positive or negative) depth value. The device 1 receives a signal from the reader 4 of the magnetic marks in the form of a voltage level, performs an analog-to-digital conversion and digitally calculates the detection of the magnetic mark, in accordance with the polarity of the mark set by the user and the specified sensitivity. Label detection is signaled by a buzzer and the ignition of the LED on the display of the device 1, at the same time, the device 1 transmits to the geophysical logger a magnetic label pulse of calibrated duration. If the user is allowed to automatically correct the readings of the device 1, the adaptive synchronization algorithm for magnetic marks is turned on and, when synchronization is achieved, the device 1 corrects the depth readings on its display. If the user is allowed to record the magnetic mark in the registration memory, the device 1 registers the detection of the magnetic mark with reference to real time and depth. The device 1 receives a signal from the unit 3 measuring the tension force in the form of a voltage level, performs digital-to-analog conversion and digitally calculates the tension force of the geophysical cable in accordance with the parameters obtained with

calibration of the unit 3. The obtained value is displayed on the display of the device 1 in units of force (kg or × 10 kg). At the same time, the current force value is compared with the maximum allowable value specified by the user. When the measured value reaches the set maximum, the device 1 generates an output blocking signal and turns on the buzzer alarm. If the user is allowed to register the tension, the device 1 writes to the memory the magnitude of the tension force with reference to real time in accordance with the established registration parameters. Instrument 1 transmits the current state of monitored values (depth, speed, tension, detection of a mark) at the request of a computer to display them on a monitor screen and for registration purposes. If a request is received from the computer to upload the data recorded in the registration memory, device 1 will transmit the contents of the requested data page. When the power is turned off, instrument 1 saves all parameter settings, including the current depth at the time of shutdown.

Using the complex for monitoring and measuring the parameters of hoisting operations allows measuring and indicating the length of the geophysical cable, the speed of lifting and lowering of downhole tools, the tension force of the geophysical cable, reading the magnetic marks of the cable, followed by their registration and transmission, and generating warning and alarm signals in depth and cable tension

The claimed technical solution made it possible to place the measuring units directly at the mouth of the investigated well, as a result of which the accuracy of measuring the parameters of the well and ease of operation are ensured.

The inventive complex for monitoring and measuring the parameters of hoisting operations meets the requirement of industrial applicability and can be performed on standard processing equipment using modern materials and technologies.

Claims (3)

1. A complex for monitoring and measuring the parameters of hoisting operations, containing a device for recording and processing data associated with units for measuring the depth and tension force of the cable, mounted on a holding mechanism, and having an analog-to-digital converter, a unit for setting the limit values of the controlled parameters, a light unit and an audible alarm, an indication unit, calibration and portable memory units, an intrinsically safe unit and a display panel, characterized in that it further comprises a magnetic tag reader th with the data recording and processing device, as the holding mechanism of the cable tension force measuring unit and the depth measuring unit, the cheeks of the lower balance block roller and their guides are used respectively, while the depth measuring unit has a gear for engaging with the lower roller gear, and on the housing cover of the indicated block contains connectors for connecting a cable tension measuring unit, a magnetic tag reader, and a data recording and processing device. 2. The complex according to claim 1, characterized in that the unit for measuring the cable tension force consists of a strain gauge bridge and a normalizing instrument amplifier. 3. The complex according to claim 1, characterized in that the magnetic tag reader is made in the form of a sealed cylindrical container, in which a sensing element is placed that senses an external magnetic field and converts it into voltage, an instrumental amplifier and a supply voltage stabilizer.