RU51100U1 - SYSTEM FOR MEASURING THE VOLUME, DENSITY AND TEMPERATURE OF THE FLUSHING LIQUID IN RECEPTION AND FILLING TANKS - Google Patents

Abstract

The utility model relates to measuring equipment and can be used to measure the volume, density and temperature of liquids in reservoirs that are in contact with the atmosphere in the oil and gas exploration and exploration industries to control the volume, density and temperature of flushing fluid in the receiving and refilling capacities of drilling rigs when drilling wells . The technical result of the proposed utility model is the development of a system for measuring the volume, density and temperature of the washing liquid, which ensures an increase in the accuracy of the determined parameters, as well as an increase in the reliability of the system and a decrease in the complexity of maintenance due to simplification of the design. The essence of the utility model is that it offers a system for measuring the volume, density and temperature of flushing fluid in the receiving and refilling tanks of a drilling rig, containing at least two measuring modules, each of which represents a structure consisting of two coaxially arranged pipes, connected in the upper part with a sealed compartment in which the level, pressure and temperature indicators of the washing liquid are located, the electronics unit, the measuring modules are equipped with brackets for mounting tained in tanks and are connected with cables information placards driller. The level meter located in the sealed compartment of the measuring module, it is proposed to perform in the form of a high-precision volumetric reversible flowmeter-counter, the input of which is connected to the annular space of the coaxial tubes, the output is in communication with the atmosphere. The pressure meter located in the sealed compartment of the measuring module can be made in the form of a high-precision quartz pressure and temperature sensor, the input of which is connected to the cavity of the inner pipe, which makes it possible to measure the pressure of the liquid in the inner pipe taking into account the temperature correction and calculate the density of the washing liquid with taking into account the readings of the level meter. The measuring module may further comprise a washing liquid temperature sensor located on the lower part of the inner pipe and electrically connected to the electronics unit located in the sealed compartment. The specified temperature sensor wash liquid can be made in the form of a high-precision resistive or quartz

a thermometer. The electronics unit located in the sealed compartment of the measuring module may contain a built-in self-contained power supply, ensuring continuity of measurement. Coaxially located pipes that are part of the measuring modules can be made of high-strength fiberglass, the outer and inner walls of the pipes are coated with a fluoroplastic film. The driller’s information board may contain a keyboard for entering values of the base area of the used tanks, well diameter, calendar time, well number, setpoint values for all parameters, etc., light and sound signaling about exceeding the set point values, a calculator (controller) providing calculation functions according to predetermined algorithms based on information entered from the keyboard and received from the measuring modules via information cables, the total volume of flushing fluid in the tanks and and absorption intensity of the influx while drilling tool, and lifting the indicators measured and calculated parameters, and an interface for information transfer station geotechnical studies on workstation drilling master supervisor and the upper level control the drilling operations.

Description

The utility model relates to measuring equipment and can be used to measure the volume, density and temperature of liquids in reservoirs in communication with the atmosphere, in particular in the oil and gas exploration and exploration industries to control the volume, density and temperature of flushing fluid in the receiving and refilling tanks of drilling rigs when drilling wells.

The sets of instrumentation that the rigs are equipped with, as a rule, include sensors of the level of the pancreas in the receiving and refilling tanks, which serve to control the absorption and inflow of the pancreas during drilling, as well as to control the topping of the well when lifting the drilling tool and eliminating catastrophic absorption (Lukyanov E.E., Strelchenko V.V. Geological and technological research in the process of drilling. - M.: Oil and gas, 1997, pp. 544-462).

Known level sensors of float type: ПУР, ДУ-1, ПУ-1 (Demikhov V.I. Means of measuring parameters of well drilling. Reference manual. - M .: Nedra, 1990), The measurement error of such sensors is ± 1.5-2 , 5% of the upper limit of measurement (1.6-2.5 m). The disadvantages of the known float level sensors are the low accuracy of their readings associated with the sticking of a solid phase of the pancreas and a change in the density of the pancreas, as well as the complexity of the design of the sensors, leading to frequent failures. Currently, the production of these sensors is discontinued.

From information sources (Emerson Process Management. Equipment of the future, available today! - Emerson Process Management. Printed in Russia. Edition 4, 01.2004) and (KROHNE level measuring instruments. - KROHNE, 04.2004. - 7.02366.23.00) contactless acoustic and radar level gauges that have high level accuracy (error ± 5-20 mm), but using them to measure the level of the pancreas in tanks is problematic due to the presence of foam on the surface of the liquid, as well as ice crusts at low temperatures. An additional constraining factor is the extremely high prices of these level gauges.

Along with level sensors, well-known control systems contain hardware for measuring the density of the pancreas as a parameter that determines the pressure on the formations and the walls of the well, energy transfer from the pump to the bottomhole

hydraulic motor and bit nozzles, erosion of rock at the bottom, etc. Strict requirements are imposed on maintaining a given density and its exact determination. The error in measuring the density of the pancreas should not exceed 20 kg / m ³ in the measuring range 800-2640 kg / m ³ (Lukyanov E.E., Strelchenko V.V. Geological and technological research in the process of drilling. - M.: Oil and gas 1997, pp. 489-504).

For continuous automatic measurement of pancreatic density, weight densitometers are used, in which a certain volume of liquid is weighed; hydrostatic densitometers measuring the pressure of a liquid column of constant height (piezometrics also apply to them); float densitometers based on determining the buoyancy force equal to the weight of the displaced fluid, and resonance (vibration-mass) densitometers based on a change in the vibrational (attached) mass, which in turn is determined by a change in the resonant frequency.

Weighing densitometers include the automatic densitometer AVP-1 (V. Demikhov. Means of measuring the parameters of well drilling. Reference manual. - M .: Nedra, 1990), which has been discontinued to date. The disadvantages of AVP-1 include the need to use a special pump for pumping the pancreas and the greater dependence of its readings on the vibrations to which the drilling rig is exposed when operating piston pumps.

The hydrostatic densitometers include a ПЗ-1 ПЖ piezometric densitometer, the principle of which is based on the conversion of the air pressure difference in piezometric tubes immersed in the ПЖ at different depths into a proportional pneumatic signal (V. V. Demikhov. Measuring tools for well drilling parameters. Reference manual . - M .: Nedra, 1990). To date, it has also been discontinued. The disadvantages of the PP-1 densitometer are: the need to have a source of compressed air, the use of pneumatic transducers and a recorder that are not used in drilling practice, and also insufficient measurement accuracy (27 kg / m ³ ).

Hydrostatic densitometers, similar to the PP-1 densitometer with air supply to piezometric tubes, are used by many foreign service companies supplying drilling process control devices. This type of instrument includes a system for controlling the density and temperature of a TD-2000 solution of M / D TOTKO firm (Lukyanov E.E., Strelchenko V.V. Geological and technological research during drilling. - M.: Oil and gas, 1997, p. 500), which has a high accuracy (± 12 kg / m ³ ) in density and a sufficiently low accuracy (± 1.2 ° C) in temperature. The disadvantages of the TD-2000 system include greater complexity due to the presence of air treatment units,

blocks of pneumatic converters, as well as the need for constant maintenance and high cost.

Simpler and more reliable are hydrostatic densitometers that do not use an air supply and have two pressure sensors located with a spacing of 150-400 mm (measurement base) on a rod lowered into a receiving tank. An example of such a densitometer is the densitometer of the company RIGSERV LTD [(Lukyanov E.E., Strelchenko VV Geological and technological research in the process of drilling. - M .: Oil and gas, 1997, p.501), which supplies complex systems of the drilling process.

The disadvantages of the densitometers of this design are a large influence on their readings of solid phase adhesion on the separation membranes and low accuracy due to the small measurement base.

Closest to the claimed system is the integrated solution "Solution-1", containing measuring elements for continuous measurement of density, temperature, level (volume) and the intensity of the influx / absorption and topping of the pancreas in the working tanks and the filling capacity of the drilling rig. Complex equipment “Mortar-1” is included in the set of geological and technological research stations “Razrez”, “Sirius” (Lukyanov E.E., Strelchenko VV Geological and technological research during drilling. - M.: Oil and gas, 1997, p. 504) and is currently used in drilling rigs. The complex equipment “Solution-1”, having high metrological indicators (error in determining the density ± 10 kg / m3, temperature ± 0.1 ° C, level ± 2 mm, etc.), also has a number of disadvantages, which should include the following: since the measuring elements (pressure receivers) are immersed in the pancreas (on the basis of 300 mm) for the normal operation of the density and level meters, it is necessary to daily clean the receiving part of the pressure meters from adhering solid phase; complex equipment "Solution-1" is difficult to manufacture; it is impossible to replace the primary converters included in the solution-1 set directly with the drilling rig.

The technical result of the proposed utility model is the development of a system for measuring the volume, density and temperature of flushing fluid in the receiving and refilling tanks of a drilling rig, which improves the accuracy of the determined parameters, as well as improves the reliability of the system and reduces the complexity of maintenance due to simplification of the design.

The technical result is achieved by the fact that a system was developed for measuring the volume, density and temperature of the flushing fluid in the receiving and refilling tanks of the drilling rig, which contains at least two measuring modules, each of which represents a structure consisting of two coaxially arranged

pipes connected in the upper part to a sealed compartment in which the level, pressure and temperature indicators of the washing liquid are located, the electronics unit, the measuring modules are equipped with brackets for installation in tanks and connected by information cables to the driller's information board.

The level meter, located in the sealed compartment of the measuring module, can be made in the form of a high-precision volumetric reversible flowmeter-counter, the input of which is connected to the annular space of the coaxially arranged pipes, the output communicates with the atmosphere.

The pressure meter located in the sealed compartment of the measuring module can be made in the form of a high-precision quartz pressure and temperature sensor, the input of which is connected to the cavity of the inner pipe, which makes it possible to measure the pressure of the liquid in the inner pipe taking into account the temperature correction and calculate the density of the washing liquid with taking into account the readings of the level meter.

The measuring module may further comprise a washing liquid temperature sensor located on the lower part of the inner pipe and electrically connected to the electronics unit located in the sealed compartment.

The specified temperature sensor wash liquid can be made in the form of a high-precision resistive or quartz thermometer.

The electronics unit located in the sealed compartment of the measuring module may contain a built-in self-contained power supply, ensuring continuity of measurement.

Coaxially located pipes that are part of the measuring modules can be made of high-strength fiberglass, the outer and inner walls of the pipes are coated with a fluoroplastic film.

The driller’s information board may contain a keyboard for entering values of the base area of used tanks, well diameter, calendar time, well number, setpoint values for all parameters, etc., light and sound signaling when setpoint values are exceeded, a calculator (controller) providing calculation functions according to predetermined algorithms based on information entered from the keyboard and received from the measuring modules via information cables, the total volume of flushing fluid in the tanks and and absorption intensity of the influx while drilling tool, and lifting the indicators measured and calculated parameters and information transmission interface geotechnical station

research, to the workplace of the drilling foreman, supervisor and to the upper level of drilling management.

Figure 1 presents the location of the proposed system for measuring the volume, density and temperature of the drilling fluid in the receiving and refilling tanks. Figure 2 shows the design diagram of a separate measuring module, which is part of the system.

The measurement system shown in Fig. 1 combines several measurement modules 1. The number of modules 1 included in the measurement system corresponds to the number of topping and receiving containers 2. Each measurement module 1 is equipped with a bracket 3 for installation on the walls of the container 2, connected to a source power supply and is connected by information cable 4 to the information panel of driller 5.

Presented in FIG. 2, the measurement module included in the measurement system comprises an assembly of two coaxially arranged fiberglass pipes of different diameters — the outer pipe 6 and the inner pipe 7. The length of the pipes is about 2200-3000 mm. The upper parts of the coaxially arranged pipes 6 and 7 are sealed with threaded connections to the base 8 of the pressurized compartment 9 formed by a cylinder 10 screwed into the base 8 and a cap 11 covering the upper part of the cylinder 10. Inside the compartment 9 are placed a quartz pressure sensor 12 and temperature in contact with the cavity of the inner pipe 7 through the hole 13, a volumetric gas flow meter 14, the inlet of which through the tube 15 and the fitting 16 is connected to the annular space formed by the assembly of pipes 6 and 7, the output of the volumetric flowmeter 14 of tube 17 and fitting 18 communicates with the atmosphere, the electronics unit 19 with built-in lithium battery mounted on racks, not shown in Figure 2. On the outer surface of the pipe 7 at a distance of 100-200 mm from its lower cut is a sensor 20 of the temperature of the pancreas. The temperature sensor 20 of the pancreas is connected by a cable 21, laid along the outer surface of the pipe 7 with a sealed connector 22, mounted on the base 8 from the side of the sealed compartment 9. On the cover 11 of the sealed compartment 9 there are sealed power connector 23 for supplying power to the electronics, connector 24 for removal and transmission of information signals from the output of the electronics unit 19 to the information board 5 and the handle 25. The lower part of the assembly of coaxially arranged fiberglass pipes 6 and 7 is tucked into a centralizer 26 with protective arcs 27.

The claimed system operates as follows. The measuring modules 1 included in the measurement system, using the handles 25 are installed in each tank on

brackets 2, made, for example, in the form of hinged holders, the fixed part of which is attached to the wall of the tank, and the movable allows you to immerse the measuring module under the pancreas level to the required depth. A centralizer 27 with protective arcs 28 prevents the assembly of coaxially located pipes 6 and 7 from settling into the sediment at the bottom of the tank, the base 8 of the pressurized compartment 9, in which the measuring and electronic equipment is located, is significantly higher than the maximum level of the pancreas. When the lower part of the annulus is filled with flushing liquid, air is displaced, which enters the gas through the nozzle 16 and the tube 15 into the volumetric flowmeter 14, and enters the atmosphere through the nozzle 17 and the nozzle 18, and the air pressure in the annulus and the atmospheric pressure are equalized. With an increase in the level of the pancreas, air is displaced through the flow meter 14 into the atmosphere, and with a decrease in the level of air from the atmosphere passes through the volumetric flow meter 14 into the annular cavity, keeping the pressure equal to atmospheric pressure in it. Due to the reverse operation of the volumetric gas flow meter 14, the level of the pancreas is measured continuously.

The volume of air V _in , displaced from the annular cavity is equal to the volume of the pancreas V _pzh , which filled the annulus:

where h is the height of the pancreas from the lower edge of the pipes 6 and 7;

D _in - the inner diameter of the outer pipe 6;

d _n - the outer diameter of the inner pipe 7.

Since D _in and d _n are constant, the cross-sectional area of the annulus is also constant

Then

but

From (3) it follows that the resolution for measuring the level Δh is determined by the resolution for measuring the volume ΔV _in and the cross-sectional area of the annulus S.

So, for the used volumetric flow meter-counter OR-40/32, the working volume ΔV _in = 1.25 cm ³ . When D _in = 13.25 cm and d _n = 4.0 cm S = 125.25 cm ² .

Then , which is more than an order of magnitude better than the resolution of the most advanced radar level gauges (Emerson Process Management. Equipment of the future, available today! - Emerson Process Management. Printed in Russia. Edition 4, 01.2004) and (KROHNE level measuring instruments. - KROHNE, 2004.04. - 7.02366.23.00).

Assuming that the level resolution in the actual operating conditions of the level gauge when using the displacement method for measuring it does not exceed ± 0.2 mm with a measurement range of 2000 mm, we obtain a level measurement error of ± 0.01%.

The electronics unit 19, which has constantly on power from the built-in lithium battery, ensures continuous measurement. The electronics unit 19 determines the direction of rotation of the rotor of the volumetric gas flow meter 14, summarizes the displaced volume with the “+” sign, and the air entering the annulus (when the level decreases) with the “-” sign. The displacement method implemented in this system makes it possible to constantly monitor the level of pancreas in containers according to expression (3). The electronics unit 19 provides for the recognition and conversion of signals received from the temperature and pressure sensor 12, the volumetric gas flow meter 14, and also from the temperature sensor 20, coming through the cable 21 through the connector 22.

To calculate the density of the washing liquid, pressure values determined using a sensor 12 (adjusted for temperature determined by the same sensor 12) and the value of h calculated by formula (3) based on the readings of a volumetric flow meter 14 are used.

The density ρ in the interval h is calculated by the expression

where P is the pressure in the inner pipe 7, measured by the sensor 12,

h is the level determined by the expression (3).

From (4) it follows that, with high accuracy in determining h, the resolution for measuring the density Δρ is determined by the resolution in pressure ΔР.

For example, when using the PDTK-R-M quartz pressure and temperature transducer ([PDTK-R-M quartz pressure and temperature transducer. Prospect OJSC SKTB ElPA, 2002) with a measuring range of 0-0.06 MPa (0-6000 mm .vod.st) and a frequency variation range from 300 to 3000 Hz pressure resolution will be 6000 / (3000-300) = 2.22 mm / Hz. Then the error of determination

, which is much less than the regulated error (Lukyanov E.E., Strelchenko VV Geological and technological research in the process of drilling. - M: Oil and gas, 1997, pp. 454-462). Taking into account the actual measurement conditions, it can be argued that the real error in the measurement of pancreatic density will be no worse than 0.1-0.2%.

The implementation of the measurement of the true temperature of the pancreas by a temperature sensor 20 located in close proximity to the pancreas, according to standard schemes using both resistive and quartz temperature sensors with a time constant of τ≈5 s, guarantees the determination of the temperature of the pancreas with an error of not more than ± 0.1 ° С .

Thus, the high accuracy characteristics of the system for measuring the level, density and temperature of the pancreas in the receiving and refilling capacities of the drilling rig, the simplicity of the design of the system and its minimal maintenance ensure the achievement of the technical result of the claimed utility model.

The calculation of the volume of the pancreas in the tank is performed by the expression:

where h _e is the current value of h in the tank,

S _e - the area of the base of the tank is a constant value, its value is entered into the controller of the electronics unit through the keyboard of the information panel 3 drillers for each tank.

The error in determining the current volume in the tank ΔV _e is determined by the error in determining Δh _e (± 0.2 mm).

For example, for a tank with an area of 20 m ^{2, the} error in determining V _e can be ΔV _e = 0.0002 · 20 = 0.004 m ³ = 4 l.

The summation of the volume of the pancreas in all n tanks involved in the circulation of the pancreas is carried out according to the expression:

The intensity of absorption / inflow per unit time (l / h) or per unit of penetration (l / m) is determined by the expressions:

Where - specific absorption / influx in time,

- the total volume of the pancreas in the tanks involved in the circulations at time t ₁ ,

- the total volume of the pancreas in the tanks involved in the circulations at time t ₂ ,

- change in the volume of the well due to its deepening from depth H ₁ to depth H ₂ over time from t ₁ to t ₂ (calculated taking into account the diameter of the well).

Where - specific absorption / inflow in depth,

, - the total volume of the pancreas in the tanks involved in the circulation at well depths H ₁ and H _2, respectively,

- change in the volume of the well due to its deepening from depth H ₁ to depth H ₂ (taking into account the diameter of the well).

The measurement of the volume of topping the pancreas into the well when lifting the tool is carried out according to the testimony of the measuring modules located in the topping tanks.

Topping is stopped when the topped pancreas appears in the gutter, and then in the receiving tanks and the volume balance of the topped up liquid V _{dol is} compared with the volume V _in occupied by the extracted tool, which is determined by the formula:

where V _{beats sv} - specific volume of the body of one candle, l

n is the number of candles extracted.

If V _dol = V _in , the well does not absorb, when V _dol > V _{in the} well absorbs with intensity:

where (t ₂ -t ₁ ) is the time between two toppings.

If V _dol <V _in - the well shows with intensity:

The values of inflow / absorption and data on top-up tanks during the lifting of the tool are displayed on the information panel of the driller. When the inflow / absorption values exceed the limits (settings) set in advance (using the keyboard), a light and sound alarm is activated informing the driller about the transition of the controlled parameters beyond the set limits.

The settings for inflow / absorption (as well as for density, temperature and volume in tanks) can also be entered during drilling with the supply of light and sound alarms when they are reached by one or another parameter.

Thus, the system for measuring volume, density and temperature in receiving and refill tanks essentially acquires the properties of a system for monitoring the operation of a well during the entire time of its construction.

Claims (8)

1. A system for measuring the volume, density and temperature of flushing fluid in the receiving and refilling tanks of a drilling rig, characterized in that it contains at least two measuring modules, each of which represents a structure consisting of two coaxially arranged pipes connected in the upper parts with a sealed compartment in which the level, pressure and temperature of the washing liquid are located, an electronics unit that provides the conversion of signals from the meters and the implementation of the computational function With respect to the converted signals, the measuring modules are equipped with brackets for installation in tanks and are connected by information cables to the information panel of the driller. 2. The system for measuring the volume, density and temperature of the washing liquid according to claim 1, characterized in that the level meter located in the sealed compartment of the measuring module is made in the form of a high-precision volumetric reversible flow meter-counter, the input of which is connected to the annular space of the coaxially located pipes , exit communicates with the atmosphere. 3. The system for measuring the volume, density and temperature of the washing liquid according to claim 1, characterized in that the pressure meter located in the sealed compartment of the measuring module is made in the form of a high-precision quartz pressure and temperature sensor, the input of which is connected to the cavity of the inner pipe, which makes it possible measuring the pressure of the liquid in the inner pipe, taking into account the correction for temperature, and calculating the density of the flushing liquid, taking into account the readings of the level meter. 4. The system for measuring volume, density and temperature according to claim 1, characterized in that the measuring module comprises a washing liquid temperature sensor located on the lower part of the inner pipe and electrically connected to the electronics unit located in the sealed compartment. 5. The system for measuring volume, density and temperature according to claim 4, characterized in that the temperature sensor of the washing liquid is made in the form of a high-precision resistive or quartz thermometer. 6. The system for measuring volume, density and temperature according to claim 1, characterized in that the electronics unit, located in the sealed compartment of the measuring module, contains a built-in autonomous power supply that ensures the continuity of measurements. 7. The system for measuring volume, density and temperature according to any one of claims 1 to 4, characterized in that the coaxially arranged pipes included in the measuring modules are made of high-strength fiberglass, the outer and inner walls of the pipes are coated with a fluoroplastic film. 8. The system for measuring volume, density and temperature according to claim 1, characterized in that the information panel of the driller contains a keyboard for entering values of the base area of used tanks, well diameter, calendar time, well number, setting values for all parameters, light and sound alarms about exceeding the specified values of the settings, the calculator (controller), which provides the calculation function according to the specified algorithms based on information entered from the keyboard and received from the measuring modules according to the information cables, the total volume of flushing fluid in the tanks and the intensity of inflow and absorption during drilling and lifting tools, indicators of measured and calculated parameters and the interface for transmitting information to the station for geological and technological research, to the workplace of the drilling foreman, supervisor and to the upper level of drilling operations management .