RU2079813C1 - System measuring flow rate of fluid medium - Google Patents

Abstract

FIELD: oil, petroleum refining and petrochemical industries, systems supplying and distributing liquid fuel over pipe-line, in particular, at gas-filling stations. SUBSTANCE: proposed system includes turbine flowmeter installed in pipe-line to measure flow rate of fuel in this pipe-line, volumetric device for periodic check measurement of volume of medium flowing in pipe-line during specified time period, computer to compare measured values, to correct readings of flowmeter in compliance with check measurement and to output information on current and/or summary flow rate and/or remaining fuel and indicator to display measured and calculated values. Float level gauge with contact strip installed in discharge tank or communicating with it which reference points correspond to readings of measuring scale of tank is used in the capacity of volumetric device. Float level gauge may be provided two floats for simultaneous measurement of two media present in one tank but having different densities, specifically fuel and product water. EFFECT: expanded application field, increased operational reliability. 5 cl, 3 dwg

Description

 The invention relates to measuring equipment and can be used in the oil, oil refining, petrochemical industries, mainly in the supply and distribution of liquid fuel through pipelines, in particular, at gas stations, etc.

 There are various flow meters installed in the fuel and drain pipelines of fuel consumables, operating on the principle of measuring physical quantities depending on the amount of fluid flowing, in particular, density, light and sound permeability, magnetic permeability, electrical capacitance characteristics, etc. for example, inductive (with a disturbance coil and a measurement coil), acoustic, ultrasonic, magnetic, vortex type and other flow meters.

 A disadvantage of the known flow meters is the insufficiently high accuracy of measuring the flow rate of the medium, associated with the dependence of the measured physical quantities on fluctuations in temperature, pressure, including atmospheric pressure, the uniformity of the measured medium, the presence of impurities, etc. the need to compensate for these fluctuations. In addition, there are difficulties associated with calibrating these flow meters and converting analog measurement values to digital.

 Higher stability and the ability to control and adjust the measurement results are provided by dynamic flow meters such as turbines, impellers, in particular with an electromagnetic speed meter. In this case, changes in viscosity and friction coefficient associated with the influence of temperature and pressure fluctuations, as well as deviations related to the inhomogeneity of the flow, affecting the measurement results, are monitored and corrected by installing appropriate sensors, in particular, density, an additional detector rotor measuring the measurement of the deviation angle fluid from the measuring rotor, installation behind the blades of the pitot tube, taking into account pressure changes, etc.

 Known technical solutions provide only partial control and compensation of deviations of the flow conditions from the reference and the measurement results from the actual flow rate.

Known closest to the claimed technical solution, selected as the closest analogue, a system for measuring liquid in a pipeline, comprising a dynamic flowmeter in communication with the pipeline or installed in it, in particular a turbine flowmeter, for measuring liquid flow in this pipeline, a volumetric device for periodic monitoring measurement the time during which a certain volume of liquid flows through the pipeline, in the form of a measuring chamber with a channel for draining liquid from boprovoda and its return duct into the conduit; a device for converting electrical quantities produced by meters into quantitative units of volume and / or mass, a computing device for comparing measured values, correcting the flow meter readings in accordance with the control measurement and outputting information about the current and / or total fluid flow rate, as well as a device for indicating measured or calculated quantities [2]
The use of a volumetric device for the control measurement provides information on the actual volume of the medium flowing through the pipeline for a certain period of time regardless of the measurements of individual changing physical quantities and improves the accuracy of the flowmeter readings.

 A disadvantage of the known system is the discreteness of the control system and adjustment of the flowmeter, only periodic receipt of information about the actual flow rate of the liquid. This does not provide a full adjustment in accordance with the actual expense and does not allow obtaining information about the actual current and total expense. In addition, the known system does not provide information about the fractional composition of the liquid, the presence of impurities, in particular, the presence and amount of produced water in liquid fuel.

 Known volumetric device of a float type, designed for continuous measurement of fuel level in a flow tank with the possibility of recalculating the level readings in volume and / or mass with constant fixing of the total flow rate and residue [1] In this case, the equalizer is made with two floats moving on vertical guides for simultaneous measurement level of fuel and produced water in the tank. One of the floats is made in the form of a ball and has a density less than the density of the fuel, and the second float, made in the form of a cylinder, has a density greater than the density of the fuel, but less than the density of water. The guiding elements of the floats are made in the form of inductive coils-receivers connected to the floats by means of ball joint mechanisms. The emitting coils are mounted on tension strings of electric steel. The counting device consists of four voltage-frequency converters, the outputs of which are connected to the inputs of summing decimal-binary converters, the outputs of the latter to the inputs of the dividers, and the outputs of the pulse generator and dividers to the counter-decoder and to a digital indicator device.

 A disadvantage of the known device is the need to convert analog measurement values into digital level indicators, followed by conversion into volume or mass to determine the total flow or residue, which is associated with certain errors. In addition, the measurement results are not tied to time or any fixed points, which does not allow to evaluate the flow rate, its stability.

 The objective of the invention is to improve the accuracy and expansion of the measurement range of the system for measuring the flow rate of a fluid in a pipeline, in particular, in a filling and / or drain pipe of a fuel supply tank by creating the possibility of periodically adjusting the amount of medium flowing through the pipeline in comparison with the actual total flow rate, and fixing and accounting for the presence of impurities in the reservoir with a different density of produced water than the medium being measured.

 The problem is solved due to the fact that when using the design features of the known system for measuring fluid flow in a pipeline, in particular, fuel in a filling and / or drain pipe of a flow tank containing a dynamic flow meter installed in the pipeline or connected to it, in particular a turbine a flow meter, for measuring fuel consumption in this pipeline, a volumetric device for periodically monitoring the volume of the medium flowing through the pipeline for 3 hours a given period of time, a device for converting electrical quantities issued by meters into quantitative units of volume and / or mass, a computing device for comparing measured values, correcting the flow meter readings in accordance with the control measurement and issuing information about the current and / or total fuel consumption and / or remaining fuel, as well as an indicator device for indicating measured and calculated values, in accordance with the invention, an installed device is used as a volumetric device feed tank or communicating with him float level gauge with contact strip, reference points which correspond to the indications dimensional reservoir scale.

 The float level gauge can be made with two floats for the simultaneous measurement of two media in a single tank with different densities, in particular, fuel and produced water; while the floats with the appropriate buoyancy fractions are equipped with magnets and are located on each other with the possibility of movement on the same axis in the form of a hollow sealed pipe, inside of which there is a strip with magnetically controlled contacts.

 Calculation of the amount of the main fraction taking into account the volume of another fraction and transmission of information about the amount of the other fraction to the indicator device may also be included in the program of the computing device.

 The use of a volumetric device for periodic control measurement of the volume of medium flowing through the pipeline for a predetermined period of time installed in the flow tank or in communication with the float level meter allows you to adjust the current meter readings according to the actual total flow rate, which ensures the optimal level of accuracy of measuring the current flow rate.

 The use of a level gauge with a contact strip, the reference points of which correspond to the readings of the tank’s measuring scale, provides measurement results in digital level values that correspond to a predetermined volume, which facilitates the measurement and calculation process and ensures optimal accuracy. At the same time, the binding of the results of periodic control measurements to fixed points on the scale optimizes the estimation of the flow rate and its stability.

 The use of a level gauge with two floats makes it possible to control the presence of impurities such as bottom water in the tank, determine its amount and obtain information about the net balance of the measured medium in the tank.

 The combination of distinctive features provides the corrected information about the current flow rate, as well as accurate information about the total flow rate and the net balance of the measured medium in the tank, which corresponds to the task facing the invention.

 The invention is considered on the example of its implementation in the form of a system for measuring fuel consumption in a filling and drain pipe of a flow tank shown in the drawings, where: in FIG. 1 is a block diagram of a fuel consumption measuring system; in FIG. 2 turbine flowmeter, longitudinal section, in FIG. 3 two-float level gauge, longitudinal section.

 The fuel consumption measuring system includes a fueling flow meter (РЗ) 1 installed in the pipeline entering the flow tank with a converter of electrical quantities into digital (PR) 2; a discharge flowmeter (PC) 3 installed in the pipeline leaving the supply tank with a transmitter (PR) 4; a float-operated equalizer (UE) 5 installed in the supply tank with a fuel level indicator (SUT) 6 and a converter (PR) 7, as well as a water level indicator (SUV) 8 with a converter (PR) 9; microcontroller (MK) 10 and indicator device (IU) 11.

 The refueling flow meter 1 and the discharge flow meter 3 are made in the form of a turbine flow meter according to FIG. 2, which consists of a calibrated tube-shaped housing 12 with an impeller 13 mounted on a central longitudinal axis and a rev counter with a permanent magnet 14 on the impeller blades and an inductor 15 on the housing.

 The level gauge 5 consists of an open hollow cylindrical body 16 with a central guide rod 17 hollow in the form of an airtight pipe, on which floats for fuel 18 and for produced water 19 are mounted with the ability to move. The floats are equipped with permanent magnets. A contact strip with magnetically controlled contacts 20 is installed inside the hollow rod in the form of reference points corresponding to the indicators of the measuring scale of the tank.

 The system operates as follows.

 Flowmeters 1 and 3 convert the impeller speed, depending on the flow rate of the fuel flowing through the pipeline, into electrical signals. Converters 2 and 4 convert the signals from the outputs of the flow meters into rectangular pulses of a given amplitude with a repetition rate proportional to fuel consumption. The volume (mass) of the fuel passed through the flow meters is determined by summing the prices of 10 pulses received at the input of the microcontroller. The microcontroller calculates the volume (mass) of fuel in the tank by summing the price of the pulse received from the flow meter 1, or by subtracting the price of the pulse coming from the flow meter 3 with the current value of the volume (mass) of fuel in the tank. The calculation of the fuel consumption passing through the flow meters 1 or 3 occurs by summing the pulse prices from the converters 2 or 4, respectively, with the corresponding current volume (mass) of the fuel passed through the flow meters.

 Using the float level gauge 5, periodically correct the current and total consumption and the balance determined by the flow meters 1 and 3 by comparing them with the actual total consumption and the remaining fuel in the tank. In the process of changing the fuel level in the tank during the passage of the fuel float 18 past the corresponding magnetically controlled contact, it is triggered. In this case, the converter 7 generates a code number of the triggered magnetically controlled contact, which is transmitted to the microcontroller. The microcontroller corrects the values of the current and total consumption, as well as the remainder, to the actual calibrated value corresponding to the number of the activated contact and stored in its memory.

 If there is commercial water in the reservoir, the water level float switch 8 triggers the corresponding contact on the contact strip and through the converter 9, similarly to converter 7, the microcontroller receives information about the volume (mass) of produced water in the tank, which corrects the actual fuel balance in the tank by value of the volume (mass) of water.

 The measured and calculated values of the current flow rate, total flow rate and the remainder of the fuel, as well as water, are transmitted to the indicator device 11.

 The invention is original, involves an unconventional direction in solving the problem, allows simple means to optimize the process of correction of measured values, can be implemented industrially using well-known technical means, technologies, materials and components.

Claims (5)

 1. A system for measuring the flow rate of a fluid in a pipeline, in particular fuel in a filling and / or drain pipe of a flow tank with a measuring scale, comprising a dynamic flow meter installed in the pipeline or in communication with it, a volumetric device for periodically monitoring the volume of the medium flowing through the pipeline within a specified period of time, the device converting signals issued by a dynamic flow meter and volumetric device in quantitative units s volume and / or mass, a computing device for comparing the measured values, adjusting the flowmeter in accordance with the control measurement of the volume and issuing information about the current and / or total flow rate and / or the remainder of the measured fluid, as well as an indicator device, characterized in that as a volumetric device, a float level meter with a contact strip installed in the supply tank or in communication with it is used, the reference points of which correspond to the readings of the flow measuring scale Nogo tank.  2. The system according to claim 1, characterized in that a turbine flowmeter is used as a dynamic flowmeter.  3. The system according to claim 1 or 2, characterized in that the float level gauge is made in the form of two floats installed in the housing with the ability to move on an axis made in the form of a hollow sealed pipe, inside of which there is a contact strip, the reference points of which are made in the form magnetically controlled contacts, and the floats are equipped with magnets and are made of materials with varying degrees of buoyancy for simultaneous measurement of the level of two fluids in a flow tank with different densities.  4. The system according to p. 3, characterized in that fuel and produced water are used as fluids with different densities.  5. The system according to any one of paragraphs. 1 to 4, characterized in that the computing device comprises means for calculating the amount of fluid with one density taking into account the volume of fluid with a different density and transmitting information about it to the indicator device.

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