RU2308700C2 - Method and device for determining concentration of filler with coriolis flow meter - Google Patents

Abstract

FIELD: measuring technique.

SUBSTANCE: method comprises allowing the main liquid to flow through the Coriolis flow meter, measuring the density of the main liquid, and transmitting the signal containing measured value of the signal to the control system, adding the filler to the main liquid, allowing the mixture to flow through the Coriolis flow meter, and transmitting the measured value of density to the control system.

EFFECT: enhanced accuracy.

19 cl, 5 dwg

Description

Technical field

The present invention relates to the field of measuring systems and, more specifically, to a system and method that use measurements using a Coriolis flowmeter to determine the amount of proppant in a fracturing fluid.

State of the art

Oil, gas and other underground resources are obtained through well drilling. The well is drilled to a certain depth and cased with cement. The well passes through many zones underground, which are opened during drilling. To open a specific area, the drilling crew crushes the casing section in the desired area. The crushing process used may be hydraulic fracturing, pneumatic fracturing, or another type of fracturing. After crushing the casing, the drilling crew then pumps the fracturing fluid into the fracture to keep the fracture open. The fracturing fluid is held in an open fracture, but the latter is still permeable. This allows oil or gas to more easily flow through the fracture into the borehole.

Fracturing fluid consists of a base fluid and a proppant. To make the main fluid, guar gum is added to the water in a large tank. A mixer in the tank continuously mixes the guar gum and water together to make the base fluid. After mixing, the base fluid has a consistency somewhat similar to molasses (black molasses).

A proppant, such as sand, is then added to the base fluid in the tank to form a fracturing fluid. The amount of sand added depends on the type of soil, soil conditions and other factors. A mixer in the tank mixes the base fluid and sand together to form a fracturing fluid. The fracturing fluid is then pumped into the borehole to keep the fracture open. The amount of sand in the fracturing fluid determines how well the fracturing fluid can hold the crack open.

Since the amount of sand in the fracturing fluid is very important, the drilling team may wish to measure the amount of sand added. This can be a difficult process, as the fracturing fluid is usually not manufactured separately, but is continuously mixed. To determine the amount of sand in the fracturing fluid, the drilling crew uses a nuclear densitometer to measure the density of the fracturing fluid, which is pumped into the borehole. The control device receives the measured density value from the nuclear densitometer and calculates the amount of sand added to the fracturing fluid. The drilling crew can then leave the amount of sand at the desired level. An example of a system for providing fracturing fluid is described below and is illustrated in FIG.

Unfortunately, there are problems associated with the use of nuclear densitometers. For example, interstate and international transport of nuclear densitometers can be a difficult process, given laws and regulations relating to nuclear technology. There are also problems associated with the safe handling and transport of nuclear densitometers. Nuclear density meter operators must be certified specialists or licensed by the appropriate regulatory authority. Such factors make the use of nuclear densitometers undesirable.

Coriolis flowmeters are used to measure specific mass flow rate, density, and other fluid data. Examples of Coriolis flowmeters are disclosed in patents US 4109524, 1978, US 4491025, 1985 and Re 31450 dated February 11, 1982, all patents belong to J. E. Smith. Coriolis flowmeters comprise one or more straight or curved venturi tubes. Each configuration of a venturi in a Coriolis flowmeter has a set of eigenmodes, which can be simple bending, torsional, torsional, or coupled vibrations. Each venturi is driven to oscillate in resonance with one of these eigenmodes. Liquid flows into the flowmeter from a pipeline connected to the inlet of the flowmeter. The fluid is routed through the venturi tube / s and exits the flowmeter from the outlet of the flowmeter. The natural modes of oscillation of an oscillating fluid-filled system are partially determined by the combined mass of the venturi and the mass of fluid flowing through the venturi.

When fluid begins to flow through the venturi under the action of Coriolis forces, the points along the venturi have different phases. The phase on the input side of the venturi usually lags behind the oscillator, while the phase on the output side of the venturi is ahead of the generator. Strain gages are attached to the venturi tube / s to measure the movement of the venturi tube / ok and to generate strain gauge signals that indicate the movement of the venturi tube / ok.

Measuring electronic circuits or any other auxiliary electronics or circuits connected to the flowmeter receive signals from the strain gauge. Measuring electronic circuits process the load cell signals to determine the phase difference between the load cell signals. The phase difference between the two signals of the strain gauge is proportional to the specific mass flow rate of the liquid through the Venturi tube /. Measuring electronics can also process one or both strain gauge signals to determine fluid density.

Unfortunately, Coriolis flowmeters are not used to measure the density of a fracturing fluid. First, fracturing fluid is typically pumped into a borehole through a large pipe, such as an eight-inch pipe. Coriolis flowmeters are not designed large enough to measure an eight-inch flow. Secondly, most Coriolis flowmeters have curved venturi tubes. The erosive properties of the sand passing through the curved venturi do not allow the use of Coriolis flow meters with curved venturi. Sand will damage the venturi in hours. For these reasons, Coriolis flowmeters are not used to measure fracturing fluid, but continue to use nuclear densitometers.

Summary of the invention

An object of the present invention is to provide a system and method for determining the amount of proppant that uses a measurement system comprising a Coriolis flowmeter and a control system. First, the main fluid is passed through the Coriolis flowmeter. A Coriolis flow meter measures the density of the main fluid and transfers the measured density of the main fluid to the control system. Proppant is added to the base fluid to create fracturing fluid. The fracturing fluid is then passed through a Coriolis flowmeter. The Coriolis flowmeter measures the density of the fracturing fluid and transmits the measured value of the fracturing fluid density to the control system. The control system determines the amount of proppant in the fracturing fluid based on a measurement of the density of the base fluid, a measurement of the density of the fracturing fluid, and the proppant density.

The proposed measuring system allows replacing nuclear technology with Coriolis technology. Coriolis flowmeters can provide accurate density measurements while avoiding the problems associated with handling and transporting radioactive sources and instruments. Coriolis flowmeters also do not have the internal safety issues inherent in a nuclear densitometer.

In another example of the invention, the Coriolis flowmeter is designed to produce a sliding flow of material. In order to provide a sliding flow, the measuring system further comprises a first tube and a second tube. The first end of the first tube is for connecting to the inlet of the Coriolis flowmeter, and the second end of the first tube is for connecting to the drain of the tank. The first end of the second tube is intended to be connected to the outlet of the Coriolis flowmeter, and the second end of the second tube is intended to be connected to the reservoir. The first tube receives a sliding flow of material from the tank drain. A sliding stream moves through the first tube through the Coriolis flowmeter, through the second tube and back into the tank. Sliding flow provides a lower flow rate for measurement, such as a flow rate of one inch.

Other examples of the invention are disclosed below.

The following are aspects of the present invention. According to one aspect of the invention, the measuring system comprises a Coriolis flowmeter and a control system, wherein the measuring system is characterized in that:

Coriolis flowmeter is designed to measure the density of the main fluid flowing through the Coriolis flowmeter, to measure the density of the main fluid, transmit the measurement of the density of the main fluid, obtain a sliding fluid flow for fracturing and measure the density of the fracturing fluid, measure the density of the fracturing fluid flowing through the Coriolis flowmeter to measure the density of the fracturing fluid, the fracturing fluid containing a mixture of a base fluid and p sklinivayuschego filler, and transmitting the measured density of the fluid fracturing,

wherein the control system is designed to receive the measured density of the base fluid and the measured density of the fracturing fluid and determining the amount of proppant in the fracturing fluid based on measuring the density of the base fluid, measuring the density of the fracturing fluid and the proppant density.

Preferably, the Coriolis flowmeter comprises a straight tube Coriolis flowmeter.

Preferably, the measurement system further comprises

a first tube having a first end for connecting to an inlet of a Coriolis flowmeter and a second end for connecting to a drain of the tank,

a second tube having a first end for connecting to the outlet of the Coriolis flowmeter and a second end for connecting to the reservoir,

moreover, the first tube is designed to receive a sliding material flow ((two-phase) flow with slip of phases) from the drain of the tank, and the sliding flow moves through the first tube, through the Coriolis flowmeter, through the second tube and back to the tank.

Preferably, the control system is designed to determine the density of the proppant.

Preferably, the control system comprises a display system for displaying the amount of proppant to the user.

Preferably, the control system comprises an auxiliary interface for transmitting a signal representing the amount of proppant to the auxiliary system.

Preferably, the control system comprises a user interface for obtaining proppant density input by the user.

Preferably, the control system is for

fracturing fluid velocity calculations,

determining if the threshold value exceeds the fracturing fluid velocity,

indications if the fracturing fluid velocity exceeds a threshold value.

Preferably, the control system is for

calculating the average density of the base fluid based on a plurality of measurements of the density of the base fluid using a Coriolis flowmeter,

determining the amount of proppant in the fracturing fluid based on the average density of the base fluid; measuring the density of the fracturing fluid and the density of the proppant.

Preferably, the Coriolis flowmeter is designed to measure the specific mass flow rate of the fracturing fluid and providing at least one of the specific mass flow rates of the fracturing fluid and controlled gain of the Coriolis flowmeter to the control system,

wherein the control system is designed to provide at least one of the specific mass flow rates of the fracturing fluid and the controlled amplification of the Coriolis flowmeter for the user.

According to another aspect, a method for measuring the amount of proppant in a fracturing fluid is provided, wherein

determine the density of the proppant,

the method is characterized in that

measure the density of the main fluid using a Coriolis flow meter,

receive a sliding fluid flow for fracturing in a Coriolis flowmeter for measuring the density of the fluid for fracturing;

measuring the density of the fracturing fluid using a Coriolis flowmeter, the fracturing fluid containing a mixture of a base fluid and a proppant,

the amount of proppant in the fracturing fluid is determined based on the measurement of the density of the main fluid, the measurement of the density of the fracturing fluid and the density of the proppant.

Preferably, for measuring the density of the fracturing fluid, a density of the fracturing fluid is measured in a straight tube coriolis flowmeter using a Coriolis flowmeter.

Preferably, in the method, the first end of the first tube is further connected to the inlet of the Coriolis flowmeter, the second end of the first tube is connected to the drain of the tank, the first tube receives a sliding material flow from the tank drain, the sliding flow moves through the first tube, through the Coriolis flow meter, through the second tube and back to the tank.

Preferably, the method further comprises the step of providing an amount of proppant to the user.

Preferably, the method further comprises transmitting a signal representing the amount of proppant to the auxiliary system.

Preferably, the method further comprises the step of obtaining proppant density from the user.

Preferably in the method further

fracture fluid velocity is calculated,

determine if the threshold value exceeds the speed of the fracturing fluid,

provide an indication if the fracture fluid velocity exceeds a threshold value.

Preferably in the method further

calculating the average density of the base fluid based on a plurality of measurements of the density of the base fluid by means of a Coriolis flowmeter,

determine the amount of proppant in the fracturing fluid according to the average density of the main fluid, measuring the density of the fracturing fluid and the density of the proppant.

Preferably, the specific mass flow rate of the fracturing fluid is additionally measured using a Coriolis flow meter, at least one of the specific mass flow rate of the fracturing fluid and the controlled reinforcement of the Coriolis flow meter are reported to the user.

Brief Description of the Drawings

The invention is further explained in the description of a preferred embodiment of the invention with reference to the accompanying drawings, in which:

figure 1 depicts a known system for supplying fluid for fracturing into a borehole;

figure 2 depicts a diagram of a measuring system according to the invention;

figure 3 - diagram of a control system according to the invention;

4 is a diagram of a Coriolis flowmeter according to the invention;

5 is a flowchart for operating a measuring system according to the invention.

DETAILED DESCRIPTION OF PREFERRED EMBODIMENTS

Figure 1 presents a known system for supplying hydraulic fluid for fracturing into a borehole.

The system 100 for supplying hydraulic fracturing fluid 102 to a borehole comprises a reservoir / mixer 110, a recirculation pipe 111, a supply pipe 112, a drain pipe 118, a valve 113, a pump 128, a nuclear density meter 114, and a control device 116. A drain pipe 118 is connected to a tank / mixer 110 at one end and to a valve 113 at the other end. Pump 128 and nuclear densitometer 114 are connected via a drain pipe 118. A recirculation pipe 111 is connected to a valve 113 at one end and to a tank / mixer 110 at the other end. The supply pipe 112 is connected to the valve 113 and transports the fracturing fluid 102 to the borehole. The valve 113 directs the fracturing fluid 102 either through the recirculation pipe 111 or through the supply pipe 112. The supply pipe 112, the recirculation pipe 111, and the drain pipe 118 have at least an eight inch diameter. The control device 116 is connected to a nuclear densitometer 114.

For mixing, water 120, resin 122 and sand 124 are added to the tank / mixer 110. In the tank / mixer 110, water 120, resin 122 and sand 124 are mixed to form a fracturing fluid 102. The amount of sand added to water 120 and resin 122 in hydraulic fracturing fluid 102 depends on the type of soil, soil conditions, and other factors. The system operator 100 uses a nuclear densitometer 114 and a control device 116 to measure the amount of sand in the fracturing fluid 102.

When a full flow of fracturing fluid 102 flows through the drain pipe 118, the nuclear density meter 114 measures the density of the fracturing fluid 102. Nuclear density meter 114 transmits the measured density value to the control device 116. The density of the sand 124, the density of water 120 and the density of the resin 122 are entered into the operator control device 116. The control device 116 calculates the amount of sand in the hydraulic fracturing fluid 102 based on a measurement of the density of the hydraulic fracturing fluid 102 and the known densities of sand 124, water 120 and resin 122. The control device 116 includes a display 136. The control device provides the amount of sand in the hydraulic fracturing fluid 102 for operator using the display 136.

As described above, there are many problems associated with the use of a nuclear densitometer 114. For example, transportation of nuclear densitometers and safe care are of considerable difficulty. People working with nuclear densitometers must be graduates or licensed by the appropriate agency. All this makes the use of nuclear densitometers undesirable.

Figure 2 presents a diagram of a measuring system 200 according to the invention. The measurement system 200 is designed to operate with a fracturing fluid system 201 for supplying fracturing fluid 202 to a borehole (not shown). The fracturing fluid system 201 comprises a tank / mixer 210, a drain pipe 218, a valve 213, a recirculation pipe 211, a supply pipe 212, a pump 228, and a measuring system 200. A drain pipe 218 is connected to the tank / mixer 210 from one end and to a valve 213 s the other end. Pump 228 is also connected to drain pipe 218. A recirculation pipe 211 is connected to a valve 213 at one end and to a tank / mixer 210 at the other end. The supply pipe 212 is connected to the valve 213 and is designed to transport hydraulic fracturing fluid 202 to the borehole. Valve 213 directs the flow of material through either the recirculation pipe 211 or the feed pipe 212. The fracturing fluid system 201 may contain other elements that are not shown for brevity.

The measurement system 200 consists of a Coriolis flowmeter 222 and a control system 224. The measuring system 200 may also include pipes 226, 227, which form a sliding stream from the drain pipe 218. Pipes 226, 227 may be one inch rubber tubes. The pipe 226 includes ends 271 and 272. The end 271 is connected to the inlet of the Coriolis flowmeter 222. The end 272 can be connected to the elbow of the drain pipe 218 to obtain better results. The pipe 227 includes ends 281 and 282. The end 281 is connected to the outlet of the Coriolis flowmeter 222, and the end 282 is connected to the reservoir / mixer 210. The pipe 226, the Coriolis flowmeter 222 and the pipe 227 are configured to receive a sliding material stream 280. Sliding material stream 280 enters pipe 226, passes through pipe 226, through Coriolis flowmeter 222, through pipe 227, and back to tank / mixer 210.

The following definitions are provided for understanding the invention. A Coriolis flowmeter contains any meter designed to measure the density of a material based on the Coriolis law. An example of a Coriolis flowmeter is a Model T-100 straight pipe meter from Micro Motion Inc., Colorado. Hydraulic fracturing fluid contains any fluid, material or mixture used to prevent fracture crushing in a borehole and provide a permeable passage. The proppant contains any material or substance used in the fracturing fluid to keep the cracks open. An example of proppant is sand. The base fluid contains any material or substance mixed with a proppant to form a fracturing fluid. A tank or tank / mixer is any tank or container for storing material. A pipe contains any hose, pipe system, pipeline, pipe, etc.

During operation, the tank / mixer 210 receives and mixes the base fluid 250. In accordance with the position of the valve 213, the pump 228 pumps the base fluid 250 through the drain pipe 218 and the recirculation pipe 211. Sliding flow 280 of main fluid 250 enters pipe 226. Sliding flow 280 of main fluid 250 moves through pipe 226, through Coriolis flowmeter 222, through pipe 227, and back to reservoir / mixer 210. When main fluid 250 flows through Coriolis flowmeter 222, density is measured main fluid 250. Coriolis flowmeter 222 transmits the measured density value of main fluid 250 to control system 224.

Proppant 252 is then introduced and mixed into the tank / mixer 210 with the base fluid 250 to produce fracturing fluid 202. In accordance with the position of valve 213, pump 228 pumps fracturing fluid 202 through a drain pipe 218 and a recirculation pipe 211. Pipe 226 receives a sliding stream 280 of fracturing fluid 202. The fluid flow 280 of the fracturing fluid 202 moves through the pipe 226, through the Coriolis flowmeter 222, through the pipe 227 and back to the reservoir / mixer 210. When the fracturing fluid 202 flows through the Coriolis flowmeter 222, the density of the fracturing fluid 202 is measured. Coriolis flowmeter 222 transmits the measured value of the density of the fluid 202 for fracturing in the control system 224.

The control system 224 receives the density of the main fluid and the density of the fracturing fluid, as well as the density of the proppant 252. The control system 224 can obtain the density of the proppant 252 from an operator, from memory, or from another source. The control system 224 determines the amount of proppant 252 in the fracturing fluid 202 based on measuring the density of the main fluid, measuring the density of the fracturing fluid and the density of the proppant 252. The operator of the fracturing fluid system 201 can see the amount of proppant 252 in the fracturing fluid 202, determined by the control system 224 to adjust the amount of proppant 252 added to the fracturing fluid 202.

When the fracturing fluid 202 contains the proper amount of proppant 252, the valve 213 is switched so that the fracturing fluid 202 is pumped into the bottom of the well through the feed pipe 212. Other devices or systems, such as a large pump, coupled to the supply pipe 212 may be provided to pump the fracturing fluid 202 to the bottom of the well.

Figure 3 presents an example of a control system 224 according to the invention. The control system 224 includes a display 302, a user interface 304, and an auxiliary interface 306. An example of a control system 224 is Daniel®FloBoss ^TM 407. The display 302 is intended to display any relevant data to the operator. An example of a display 302 is a liquid crystal display (LCD). A user interface 304 allows an operator to input information into a control system 224. An example of a user interface 304 is a keyboard. Auxiliary interface 306 is designed to transmit information to an auxiliary system (not shown) and receive information from it. An example of an auxiliary interface 306 is a serial data port.

The control system 224 may also comprise a processor and a storage medium. The operation of the control system 224 can be controlled using commands that are stored in a storage medium. Commands can be retrieved and executed by the processor. Some examples of commands are software, program code, and firmware. Some examples of storage media are storage media, tape drives, disks, integrated circuits, and servers. The instructions are executed by the processor according to the invention. The term "processor" means a single processing device or a group of processing devices working together. Some examples of processors are computers, integrated circuits, and logic circuits. Those skilled in the art are familiar with commands, processors, and storage media.

Figure 4 presents an example of a Coriolis flowmeter 400 according to the invention. Coriolis flowmeter 400 may be Coriolis flowmeter 222 (FIG. 2). Coriolis flowmeter 400 includes a Coriolis sensor 402 and measurement electronics 404. Measuring electronics 404 is connected to Coriolis sensor 402 along path 406. Measuring electronics 404 is used to determine density, specific mass flow rate, volumetric flow rate, total mass flow, and other information through path 408 .

Coriolis sensor 402 includes a Venturi tube 410, a balance bar 412, connections 414, 415, a drive 422, strain gauges 424, 425 and a temperature sensor 426. Venturi tube 410 includes a left end portion designated 410L and a right end portion designated 410R. The venturi tube 410 and its end portions 410L and 410R extend along the entire length of the Coriolis sensor 402 from the input end of the venturi 410 to the output end of the venturi 410. The balance bar 412 is connected at its ends to the venturi 410 by means of the fastening 416 of the bar.

The left end portion 410L is attached to the flow inlet 414. The right end portion 410R is attached to the flow outlet connection 415. The flow inlet connection 414 and the current output connection 415 provide a connection to the Coriolis sensor 402 with a conduit (not shown).

Typically, the drive 422, the left load cell 424, and the right load cell 425 are connected to the venturi 410 and the balance bar 412. Measuring electronics 404 transmits a signal to the drive 422 along path 432. In response to this signal, the drive 422 vibrates the venturi 410 and the balance bar 412 in antiphase at the resonant frequency of a liquid-filled venturi 410. Fluctuations in the venturi 410 in a known manner generate Coriolis deviations in the venturi 410. Strain gages 424 and 425 detect Coriolis abnormalities and transmit strain gauge signals that display Coriolis abnormalities via paths 434 and 435, respectively.

A temperature sensor 426 is connected to a venturi tube 410. A temperature sensor 426 senses the temperature of the fluid flowing through the venturi 410. The temperature sensor 426 generates a temperature signal and transmits the temperature signal to the measurement electronics 404 via path 436.

5 is a flowchart 500 during operation of the measurement system 200 according to the invention. The operator includes a control system 224 and a Coriolis flowmeter 222. The control system 224 receives a command to clear the memory. The operator clears the memory by entering the “Clear” command through the user interface 304. At step 504, the control system 224 instructs the operator to enter proppant density 252. The control system 224 instructs the operator to display “Enter proppant density” on display 302. The operator enters the density of proppant 252 (in pounds per gallon) through the user interface 304. Let proppant 252 be sand having a density of 22.1 pounds per gallon. At step 506, the control system 224 receives the proppant density signal 252 inputted by the operator. The proppant density can also be retrieved from memory or obtained from another system.

The tank / mixer 210 mixes the base fluid 250 without proppant 252. Based on the position of the valve 213, the pump 228 pumps the base fluid 250 through the drain pipe 218 and the recirculation pipe 211. Sliding stream 280 of main fluid 250 enters pipe 226. Sliding stream 280 of main fluid 250 passes through pipe 226, through Coriolis flowmeter 222, through pipe 227 and back to reservoir / mixer 210. When main fluid 250 flows through Coriolis flowmeter 222, the latter measures the density of the base fluid 250 in step 508. The Coriolis flowmeter 222 transmits the measured density of the base fluid to the control system 224. The control system 224 displays the measured value of the density of the main fluid for the operator in step 510. The Coriolis flowmeter 222 also measures the specific mass flow rate of the main fluid 250, the temperature of the main fluid 250 and other parameters in step 508. The control system 224 also displays the specific mass flow rate, temperature, and others parameters for the operator in step 510. The operator can scroll through the various parameters to see the desired parameter.

At 512, the control system 224 calculates the average density of the base fluid 250 as the average of ten measured densities of the main fluid 250. The control system 224 can also calculate the average density as the average of the measured densities over a five second interval. During the calculation of the average density, the control system 224 may display "Stabilization of the main fluid" for the operator. The control system 224 may calculate the average density in response to an operator command. For example, the operator views the measured density value and the measured temperature value displayed by the control system 224 to determine if the measurements have stabilized. If the measurements are stabilized, the operator instructs the control system 224 to calculate the average density.

At 514, the control system 224 determines whether the just calculated average density is stable. For example, if the average density changes by more than 1% over a five-second interval, the average density is unstable. In this case, the control system 224 displays “Unstable density” for the operator and returns to step 512. If the average density does not change by more than 1%, the average density is stable and can be used. The control system 224 displays the stable average density of the base fluid 250 for the operator in step 516.

At this point, the reservoir / mixer 210 mixes the proppant 252 with the base fluid 250 to form a fracturing fluid 202. Based on the position of valve 213, pump 228 pumps fracturing fluid 202 through drain pipe 218 and recirculation pipe 211. Pump 228 re-pumps the fracturing fluid to constantly mix the fracturing fluid 202 in accordance with predetermined specifications. A sliding stream 280 of fracturing fluid 202 enters the pipe 226, which passes through the pipe 226, through the Coriolis flowmeter 222, through the pipe 227, and back to the reservoir / mixer 210. When the fracturing fluid 202 flows through the Coriolis flowmeter 222, the Coriolis flowmeter 222 measures the density fracturing fluid 202 in step 518. A Coriolis flowmeter 222 transmits the measured fracture fluid density to a control system 224.

The control system 224 then calculates pounds of sand added to the fracturing fluid 202, for which control system 224 uses the following equations. At step 520, the control system 224 calculates the percentage (% S) of solids in the fracturing fluid 202 according to equation 1

% S = (ρ frac fluid - ρ base fluid) / (ρ proppant - ρ base fluid),

where ρ frac fluid - fluid density 202 for fracturing,

ρ base fluid - density of the main fluid 250,

ρ proppant - proppant density 252.

At step 522, the control system 224 calculates the displacement (P.D.) of the proppant according to equation 2

P.D. = 231 / ρ proppant,

where ρ proppant is the proppant density 252.

At step 524, the control system 224 calculates pounds (P.S.A.) of sand added to the fracturing fluid 202 according to equation 3

P.S.A. = (% S * 231) / ((1-% S) * P.D.).

Pounds (P.S.A.) of added sand may also be called pounds (P.P.A.) of added proppant.

The control system 224 can calculate pounds of added sand using equation 4 instead of equations 1-3.

(P.S.A.) = (Ρ frac fluid - ρ base fluid) / ((1- (ρ frac fluid / ρ proppant)),

where ρ frac fluid - fluid density 202 for fracturing,

ρ base fluid - density of the main fluid 250,

ρ proppant - proppant density 252.

At step 526, the control system 224 displays pounds of sand added to the fracturing fluid 202. The control system 224 displays pounds of added sand in units: pounds of added sand per gallon of water. The control system 224 also generates a signal displaying pounds of added sand. The signal may be a 4-20 mA signal for an auxiliary system (not shown). Coriolis flowmeter 222 also measures the specific mass flow rate of the fracturing fluid 202, the temperature of the fracturing fluid 202, and other parameters in step 518. The control system 224 can display the specific mass flow, temperature, and other parameters for the operator in step 526. The operator can scroll through various parameters to see the desired parameter. The control system 224 returns to step 518.

The method 500 may further include steps 528 and 530. At step 528, the control system 224 compares the speed of the fracturing fluid 202 with a threshold value. The control system 224 calculates the speed of the fracturing fluid 202 according to equation 5

velocity material = flow rate material * A.F.,

where A.F. - area factor,

flow rate material - flow rate of the material.

The area factor (A.F.) can be obtained from the operator, or retrieved from memory, or obtained in another way. If the speed of the fracturing fluid 202 exceeds a threshold value, the control system 224 provides an indication that the speed exceeds the threshold value in step 530. For example, if the fracturing fluid 202 exceeds 12 ft / sec, the control system 224 triggers an alarm. If the speed of the fracturing fluid 202 does not exceed a threshold value, the control system 224 returns to step 518.

The control system 224 continues to calculate pounds of sand added to the fracturing fluid 202. The tank / mixer 210 is a continuously mixing system, and not a periodically mixing system. Therefore, the operator receives pounds of added sand measured by the control system 224 until the reservoir / mixer 210 provides fracturing fluid 202 in the borehole.

Claims (19)

1. A measuring system (200) comprising a Coriolis flowmeter (222) and a control system (224), characterized in that the Coriolis flowmeter is designed to measure the density of the main fluid (250) flowing through the aforementioned Coriolis flow meter and generate a density signal of the main fluid, transmitting a signal of the measured density of the main fluid, obtaining a sliding fluid flow (280) of the fracturing fluid (202) for measuring the density of the fracturing fluid and generating a fluid density signal (202) for the fracturing flowing through a Coriolis flowmeter, wherein the fracturing fluid comprises a mixture of a base fluid and a proppant (252), and transmitting a signal of a measured fracture fluid density, wherein the control system is designed to receive the density signal of the main fluid and the density signal of the fracturing fluid and determining the amount of proppant in the fracturing fluid based on the measurement signal of the density of the base fluid, the measurement signal of the density of the fracturing fluid and proppant density. 2. The measuring system (200) according to claim 1, characterized in that the Coriolis flowmeter (222) contains a Coriolis flowmeter (400) with a straight pipe. 3. The measuring system (200) according to claim 1, characterized in that it further comprises a first pipe (226) having a first end (271) for connecting to the inlet of the Coriolis flowmeter (222) and having a second end (272) for connecting to the drain (218) of the tank (210), and a second pipe (227) having a first end (281) for connecting to the outlet of the Coriolis flowmeter (222), and having a second end (282) for connecting to the tank, wherein said first pipe is designed to receive a sliding stream (280) of material from the tank drain, which moves along the first pipe through the Coriolis flowmeter, the second pipe back to the tank. 4. The measuring system (200) according to claim 1, characterized in that the control system (224) is designed to determine the density of the proppant (252). 5. The measuring system (200) according to claim 1, characterized in that the control system (224) comprises a display system (302) for transmitting said amount of proppant (252) to the user. 6. The measuring system (200) according to claim 1, characterized in that the control system (224) comprises an auxiliary interface (306) for transmitting a signal that displays the indicated amount of proppant (252) to the auxiliary system. 7. The measuring system (200) according to claim 1, characterized in that the control system (224) comprises a user interface (304) designed to represent the density of the proppant (252) entered by the user. 8. The measuring system (200) according to claim 1, characterized in that the control system (224) is designed to calculate the fluid velocity (202) for fracturing, determining whether the fracture fluid velocity exceeds a threshold value, providing an indication if the fracture fluid velocity exceeds a threshold value. 9. The measuring system (200) according to claim 1, characterized in that the control system (224) is designed to calculating the average density of the main fluid (250) based on the set of measurement signals for the density of the main fluid through a Coriolis flow meter (222), determining the amount of proppant (252) in the fracturing fluid (202) based on the average density of the base fluid, the fracture fluid density signal and the proppant density. 10. The measuring system (200) according to claim 1, characterized in that the Coriolis flowmeter (222) is designed to measure the specific mass flow rate of the fluid (202) for fracturing and transferring at least one of the specific mass flow rates of the fracturing fluid and coefficient strengthening the Coriolis flowmeter in the control system (224), moreover, the control system is intended to represent at least one of the specific mass flow rates of the fracturing fluid and the gain of the Coriolis flowmeter to the user. 11. The method of measuring the amount of proppant in the fracturing fluid, which consists in determining the density of the proppant, characterized in that measuring the density of the base fluid (250) with a Coriolis flowmeter (222) to generate a density signal of the base fluid, passing a sliding stream (280) of fracturing fluid through a Coriolis flowmeter, measure the density of the fracturing fluid (202) using a Coriolis flowmeter and generate a fracture density signal, the fracturing fluid containing a mixture of a base fluid and a proppant (252), determine the amount of proppant in the fracturing fluid based on the signal density of the main fluid, the density of the fracturing fluid and the density of the proppant. 12. The method according to claim 11, characterized in that when measuring the density of the liquid (202) for fracturing using a Coriolis flowmeter (222), a Coriolis flowmeter (400) with a straight tube is used. 13. The method according to claim 11, characterized in that it further connects the first end (271) of the first pipe (226) with the input of the Coriolis flowmeter (222), connecting the second end (272) of the first pipe (226) with the drain (218) of the tank (210), connecting the first end (281) of the second pipe (227) with the output of the Coriolis flowmeter (222), connect the second end (282) of the second pipe (227) with the tank, wherein the first pipe receives a sliding stream (280) of material from the drain of the tank, and the sliding stream moves along the first pipe through the Coriolis flowmeter, through the second pipe and back to the tank. 14. The method according to claim 11, characterized in that it additionally reports the required amount of proppant (252) to the user. 15. The method according to claim 11, characterized in that they further transmit a signal representing the said amount of proppant (252) to the auxiliary system. 16. The method according to claim 11, characterized in that it further takes the value of the density of the proppant (252) from the user. 17. The method according to claim 11, characterized in that it further computes the fluid velocity (202) for fracturing, determine whether the fracture fluid exceeds a threshold value, provide an indication if the fracture fluid velocity exceeds a threshold value. 18. The method according to claim 11, characterized in that it further calculates the average density of the main liquid (250) based on a plurality of measurements of density signals of the main liquid by means of a Coriolis flowmeter (222), the amount of proppant (252) in the fracturing fluid (202) is determined based on the average density of the base fluid, the fracture fluid density signal and the proppant density. 19. The method according to claim 11, characterized in that it further measures the specific mass flow rate of the fluid (202) for fracturing by means of a Coriolis flowmeter (222), at least one value from the specific mass flow rate of the fracturing fluid and the gain of the Coriolis flowmeter to the user are reported.

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