RU2377505C1 - Method of automated account of oil products weight released to consumers from fuel storages in vertical and horizontal tanks - Google Patents

Abstract

FIELD: measuring technology.

SUBSTANCE: weight of oil product (OP) released from a tank is calculated by means of a computer on base of volume determined in correspondence with a measured height of OP in the tank and also on base of temperature and density of OP in the tank. To check change of OP weight in the tank the weight of released OP is calculated with a computer on base of values obtained from sensors of temperature and volume installed on fuel and oil release pumps (FRP) and from sensor of density installed in pipeline supplying fuel from tanks to FRP; further, obtained values of consumption of OP in the tank and at FRP are compared and the comparing error of OP consumption in the tank is obtained in the result of comparison.

EFFECT: upgraded accuracy of measurement of volume of oil product at storage and at different modes of release and filling.

Description

The invention relates to measuring equipment, in particular to methods for automated accounting of the mass of petroleum products (NP), and can be used in fuel depots and tank farms that store petroleum products in vertical and horizontal tanks and their distribution to consumers.

The prior art method of accounting for the release of liquid by weight, described in the copyright certificate SU 887936 A1, 12/07/1981. In this method, the reservoir is filled to a predetermined lower level, the reservoir is weighed after the settling time at this level, the reservoir is filled to a predetermined upper level, the reservoir is weighed after the settling time at this level, and the difference in the obtained weighing results is determined.

However, this method cannot be used in fuel depots and tank farms, since it is not designed for use with large volumes.

As a prototype, a method of automated control and accounting of the mass of petroleum products in fuel depots and tank farms when storing them in vertical and horizontal tanks, implemented by the system for measuring the mass of light petroleum products (see. "UIP-9602 Light Petroleum Product Mass Measurement System", ATUSh Operation Manual, was adopted. 400000.01. RE Korolev, 2003). This system is designed to measure the level, density and temperature of petroleum products, the level of bottom water or ice in vertical or horizontal tanks in fuel depots, gas stations and tank farms, followed by mass calculation for accounting and technological and technological operations.

However, the method of automated control and accounting of the mass of oil products in fuel depots and tank farms when storing them in vertical and horizontal tanks, implemented by this system, does not provide the required accuracy of accounting for partial filling of the tank and partial discharge of oil products from it.

The technical result of the invention is to improve the accuracy of accounting for the mass of petroleum products in fuel depots and oil depots that store petroleum products in vertical and horizontal tanks when they are dispensed to consumers.

The specified technical result is achieved due to the fact that in the method of automatically accounting for the mass of oil in fuel depots in vertical and horizontal tanks when they are dispensed to consumers using a measuring device, the filling height of the oil is calculated and based on the calibration tables of the tank, the volume of oil in the tank is determined based on the obtained volume values and values obtained from temperature and density sensors installed in the tanks, calculate the mass of the released NP in the tank using a computer, for the same industrial a terrible time based on the values obtained from the temperature and volume sensors installed on the fuel dispenser and the density sensor installed in the line supplying fuel from the tanks to the fuel dispenser, calculate the mass of dispensed oil to the fuel dispenser using a computer, compare the obtained values of the oil flow in the tank and at the fuel dispensers, as a result of the comparison, a comparative error of the NP consumption in the tanks is obtained.

Improving the accuracy of measuring the mass of oil in the process of dispensing oil from the tank is achieved by the fact that in the method of measuring the mass of oil in fuel dispensers with fuel dispensers, including measuring the density, volume, temperature of the oil with subsequent calculation of its mass according to the formula, the density of the oil is measured at the temperature of the line by density meter installed at the outlet of the dispensing tank, then carry out the recalculation of the measured density, determine By using the standard density value at a temperature of t = 20 ° C, at the same time, in each fuel dispenser, temperature sensors measure the temperature of the oil product tempering, according to which, taking into account the calculation tables and the standard density value of the oil product at t = 20 ° C, the density of the oil product is determined at a temperature directly to each fuel dispenser, the volume is measured by a volumetric meter that has undergone selective selection and having a limit of permissible basic relative error when changed and volume 0.08-0.15%, the calculation of the mass of oil for each fuel dispenser depending on the temperature is carried out according to the formula

_NFP where M - mass of oil;

V _NFP - the volume of oil product;

ρ _knfp (t) - the density of the oil depending on the temperature in each column;

- the mode of complete discharge (filling) of oil from the tank;

- regime of periodic partial discharge and partial loading.

In a method for automatically accounting for the mass of oil products at fuel bases when they are stored in vertical and horizontal tanks, including determining the height of the oil product in the tank, followed by calculating the volume from the calibration tables taking into account the height of the filling, measuring the temperature and density of the oil with subsequent calculation of its volume and weight , entering the obtained measurement and calculation data into the PC system database, density sensors are installed along the height of the tank and through p a distance of not more than 1.0 meter from each other temperature measuring sensors, one density measuring sensor and one temperature measuring sensor are installed at the level of oil product discharge from the tank, temperature and oil product density measurements are carried out simultaneously at the same set filling level, according to the values obtained by the system PC determine the density of the oil at standard temperature or 20 ° C or 15 ° C, according to the equations that determine the dependence of the density of the oil on its density at standard temperature, taking into account the temperature of the oil product at a given height of the tank, determine the dependence of the density of the oil on the height of the tank, carry out the approximation of the density equation for the height of the tank, taking into account the linear approximation above the last wetted temperature sensor, calculate the mathematical expression of the change in density on the height of the oil in the tank with subsequent determination its mass, taking into account the volume determined by the calibration tables in accordance with the height of the oil product in the cut the boulevard, the obtained measurement and calculation data are entered into the PC database for comparative analysis, control and accounting; when oil is dispensed, the change in the mass of the oil product in the tank is determined either by taking into account the mass of oil supplied calculated on the basis of the product and oil density determined by the height of the level of exit from the tank, or through the use of high-precision fuel dispensers, taking into account temperature adjustments.

The calculation of the volume and mass of the oil product in the tank is carried out according to thin layers, for which several layers are distinguished by the height of the oil product in the tank, the amount of oil product mass in each given layer is calculated, and then the results are summed up, determining the total value of the amount of oil product mass over the entire filling height.

The proposed method is as follows.

Along the entire height of the tank, density sensors are installed and temperature sensors are installed at a distance of no more than 1 m from each other.

To determine the mass of the oil product at a given level of filling the oil product in the tank using the density and temperature sensors, determine the value of the temperature of the oil product and its density. The density of the oil product at standard temperature or 20 ° C or 15 ° C is determined from these values using tables. These data are entered into the software.

This determination of density solves two problems at once:

- the density of the incoming oil product is checked according to the invoice and these data are entered into the PC;

- having the density of the oil product at standard temperature, the density at any height of the oil product in the tank is determined with high accuracy by the formulas of the dependence of density on temperature.

According to equations determining the dependence of density

the oil product from its density at standard temperature and temperature at a given height of the tank, the dependence of the density on the height of the oil product in the tank is determined.

Having the data of temperature sensors at various levels of oil in the tank, we approximate this curve by a mathematical formula that ensures maximum approximation to the measured temperatures at different levels t = f (h _nl ).

Let us now consider the possibility of determining the density of a petroleum product depending on its density at standard temperature for various temperatures. For any oil product, the dependence of density (ρ) on temperature is linear

where t is the temperature of the oil product;

A _t and A _ρ are the coefficients of temperature and density.

Using data on the density and temperature of the oil product, measured at the same tank level, and the table (GOST 3900-85), we find the density of the oil product at a standard temperature, for example, 20 ° C.

Example 1

Let the oil product be diesel fuel (winter) and its density at 20 ° С will be 805 kg / m ³ (0.805 g / cm ³ ).

Then equation (1) takes the form

where - 0,00072 - temperature coefficient for winter fuel;

- коэффициент плотности для зимнего топлива.

- density coefficient for winter fuel.

From equation (2) we determine the coefficient

=0,805+0,00072·20=0,8194.

= 0.805 + 0.00072.20 = 0.8194.

Then the equation of density (1) for this type of oil (p ^winters) takes the form:

Using equation (3), it is possible to compile a table with density data on the temperature of the oil product by the height of the filling in the tank for diesel fuel (winter). Then, according to standard approximation programs, using a PC system, we approximate the data obtained and obtain the equation of the density dependence curve for diesel fuel (winter) over the filling height in the tank.

For different types of fuel and under different storage conditions, the equation of the curve of the dependence of the density of the oil on the height of the filling in the tank will be different.

The proposed method allows to determine the dependence of the density of the oil on the filling height in the tank for any type of fuel under various storage conditions in vertical and horizontal tanks.

Example 2

Consider the example of calculating and plotting the dependence of the density of the oil on the height of the filling in the tank, for example, for diesel fuel (summer).

For diesel fuel (summer), equation (1) with a standard density of oil at 20 ° C of 0.820 g / cm ³ takes the form

where - 0,00071 - temperature coefficient for summer fuel;

And _ρ ^l is the density coefficient for summer fuel.

From equation (4) we determine the coefficient A _ρ ^l

And _ρ ^l = 0.830 + 0.0007120 = 0.8442.

Then, the density equation (1) for summer diesel fuel (ρ _l ) takes the form:

Using equation (5), we compile a table in which we enter the density data on the temperature of the oil product by the height of the filling in the tank for diesel fuel (summer).

The value of the temperature and density of the oil at the height of the tank Installation height of the temperature sensor from the bottom, m Temperature ° C Density of diesel fuel (summer) 1,5 fifteen 0.8336 2.5 16,2 0.8327 3,5 17 0.8321 4,5 17.6 0.8317 5.5 18.1 0.8313 6.5 18,4 0.8311 7.5 18.7 0.8309 8.5 19 0.8307 9.5 19.2 0.8306

Using the data in the table and standard approximation programs by means of a personal computer, we obtain the equation and a graphical representation of the curve of the dependence of the density of summer diesel fuel over the filling height in the tank.

where ρ _L - density;

h is the filling height of the NP in the tank;

0.8342 - coefficient.

Temperature values can be determined both by temperature sensors and by the approximating curve obtained in a PC. Further, according to the filling height, temperature under standard conditions and the above formulas (1-6), to determine the density of a given petroleum product by temperature, the density of the petroleum product is determined at different tank heights, then a mathematical approximation of this dependence is carried out according to standard PC programs. The resulting equation allows you to determine the mass of any layer of oil in the tank:

where Y _i is the volume of the oil product layer;

ρ _i is the density of the oil in the center of the layer.

The approximation of the oil density equation for the height of the tank, taking into account the linear approximation, is carried out above the last wetted temperature sensor.

Given that the reliability of density sensors is much lower than the accuracy of temperature sensors, an increase in the number of temperature sensors over the entire height of the tank and the approximation of the curve (calculated) of the change in the density of the oil product with a high degree of accuracy allows you to have a complete picture of the density change along the height of the tank.

Compared with the automated system UIP-9602 (Gamma), in which, if one or several temperature and (or) density sensors fail, the system ceases to function normally and requires repair, as a result of which it is not possible to determine the mass of the oil product. In the proposed system, in the event of the failure of one or more temperature and density sensors, the system remains operational while at least one pair of sensors is functioning normally at the same level. Using the proposed method, it is possible, and with greater accuracy, to determine the mass of the oil product, regardless of the operability of a larger number of temperature and density sensors.

In addition, due to the fact that, using the proposed method, we can obtain a mathematical expression (6) of the density change from the height of the oil product in the tank for various types of fuel and under various conditions, it is possible to increase the accuracy when determining the mass of the oil product in the tank by determining masses over fairly thin layers, characterized by a more accurate calculation of the average temperature.

In this case, the task of more accurately determining the mass of the oil product by the layers corresponding to the average temperature, and therefore the density in this layer, is solved. The layers into which the entire volume of the tank can be divided are smaller, and accordingly the accuracy of determining the mass of the oil product in the tank increases.

In this case, the mass of the oil product over the entire height of the tank is determined by simple summation of the mass values of each layer. The calculation of the remainder of the oil product in the reservoir by layers can be determined by the formula:

In this case, the volume is determined by the change in the level of oil product loading in the tank, and the density is determined by the level of oil product discharge from the tank.

The proposed method also provides a measurement of the amount of oil in vertical and horizontal tanks with higher accuracy at different modes of discharge and loading (one temperature sensor and one density sensor are installed at the drain level):

- the mode of complete discharge (filling) of oil from the tank;

- the regime of periodic partial discharge and filling.

The use of more accurate automated devices (for example, fuel dispensers with less error in measuring volume and mass and with adjustment of the volume of oil product drained from the tank according to the tempering temperature from the fuel dispenser) in the drain mode gives a more accurate picture of the mass of the dispensed oil product.

The discharge of oil from the tank is determined by the fuel dispenser, the volume - taking into account the temperature adjustment, and the mass as the amount of vacation from all columns.

The proposed method has several significant advantages.

1. Density and temperature are measured strictly at the same level.

2. According to the temperature and density, the density is recalculated programmatically to a standard temperature of 20 ° C (or 15 ° C) using GOST 3900 or tables.

3. To obtain an accurate picture of temperature changes along the height of the oil product, temperature sensors are installed no less than 1 meter to the maximum height of the spill.

4. According to the dependences of the density change on temperature, the density is recalculated depending on the filling height.

5. The density values are approximated by a mathematical method with a high degree of accuracy depending on the filling height.

6. Improving the accuracy of determining the mass of the oil product in the tank is ensured by dividing the oil product over the entire filling height by layers using calibration tables and density data for this layer. Subsequently, the mass of layers is added up.

7. The change in the mass of the oil product in the tank is determined by the mass of the supplied fuel using calibration tables and the density of the oil product at the outlet of the tank.

8. The change in the mass of the oil product in the tank can be checked with a more accurate instrument, such as a densitometer installed in the line going from the tanks to the oil product dispensing devices (for example, fuel dispensers or automated filling systems) or with high-precision fuel dispensers taking into account the oil product by volume and mass taking into account temperature adjustment.

9. In the proposed method, in the event of the failure of one or more temperature and density sensors, the system remains operational while at least one pair of sensors is functioning normally at the same level.

Let us consider an example of increasing the accuracy of accounting for the quantity of oil in vertical and horizontal tanks when tempering oil through one or more fuel dispensers. During this experiment, the following conditions must be met:

- During the experiment, no NP is loaded into the tank;

- The estimated time at which the NP is recorded in the tank (8 ⁰⁰ or 9 ⁰⁰ ) and the fuel dispenser is selected;

- At the estimated time, no NP is dispensed from the fuel dispensers to any consumers;

- The experiment involves one tank, as well as one or more fuel dispensers that are supplied with NP from this tank;

- From the first day daily, at the estimated time, the presence of NP in the tank is determined according to the Gamma system and at the same time vacation over the past day from one or more fuel dispensers;

- During the vacation time of the NP, the error of the presence of NP in the tank is checked in comparison with the data of the vacation from the fuel dispenser, where the error is obviously lower (± 0.25% by weight);

- NP costs for the reservoir are determined by more accurate data on fuel dispensers and then the error in the presence of NPs in the Gamma system will always correspond to ± 0.25% by weight and thus the availability of NPs is adjusted, which is a method of increasing the accuracy of accounting for NPs in reservoir.

Thus, if at the same time we keep records of the presence of oil products in the tank in the Gamma system during expenditure operations, then this flow should be determined by the fuel dispensers involved in expenditure operations. In this case, we can always have a guaranteed metering error of ± 0.25% by weight at any flow rate from the tank, which is impossible when accounting directly with the Gamma system. The error when accounting with the Gamma system can reach from 0.4% to 3-4%, depending on the mass of the supplied NP.

Claims (1)

A method for automatically accounting for the mass of oil products (NP) in fuel depots in vertical and horizontal tanks when they are dispensed to consumers, which includes the steps of calculating the filling height using a measuring device and determining the volume of oil in the tank using the calibration tables of the tank using computer calculate the mass of the released NP on the basis of the obtained values of the volume and values obtained from temperature and density sensors installed in the tanks, characterized in that using a computer The fuel dispenser calculates the mass of the dispensed oil on the basis of the values obtained from the temperature and volume sensors installed on the fuel and oil dispensers (dispensers) and the density sensor installed in the line supplying fuel from the tanks to the dispensers, compare the obtained values of the dispenser consumption in the tank and at the fuel dispensers, as a result of the comparison, a comparative error of the NP consumption in the tanks is obtained.