RU51008U1 - FUEL DISPLACEMENT INSTALLATION - Google Patents

Abstract

The utility model relates to fuel dispensers and is intended for refueling vehicles, spilling oil products into consumer containers during on-farm and commercial accounting operations. The technical task is to increase the accuracy of measuring the mass and volume of oil in the processes of receiving and dispensing oil from the tank, reducing the complexity and price of installations. The installation includes n> 1 dispensing tanks connected by pipelines with dispensing columns equipped with counters for measuring the volume of oil product dispensing with a limit of permissible basic relative error when the volume changes 0.08-0.15%, a software system, densitometers installed on the connecting pipelines at the exit from the dispensing tanks and temperature measuring sensors located in each dispensing column, the software system is additionally provided with information for recalculation and density by a standard value and calculating the density of the oil product at the outlet of each dispensing column according to the readings of the column temperature measuring sensor. As dispensing tanks, either fuel dispensing tanks or simultaneously fuel dispensing and oil dispensing tanks are used.

Description

The utility model relates to fuel dispensers and is intended for refueling vehicles with a tank volume of more than 400 liters, as well as spilling oil products into consumer containers during on-farm and commercial accounting operations.

Known fuel dispensers for cars, tankers, installation for refueling diesel locomotives "Alder-500".

The closest in technical essence to the claimed fuel dispensing installation is the Alder-500 installation, which includes a distribution tank connected by highways with dispensing columns equipped with counters for measuring the volume of oil product dispensing, a software system, (see Alder-500 fuel-dispensing installation, Operation manual ”, 2000).

Known plants in most cases dispense fuel by volume with an error of 0.25%. The mass measurement is carried out taking into account the density measurement at various actual temperatures of the oil in the tank. Different climatic conditions, the residence time of the oil product in the tank, the temperature of the oil product when it is discharged into the tank affect the density change in

reservoir, as well as the correct determination of the mass of oil. When storing oil product, its mass remains constant. During discharge and filling, the level of the oil product decreases (rises). Volume measurement is performed with relatively high accuracy, and the temperature range, and accordingly, the density of the oil product (average), measured by several sensors, gives a significant error in these modes when calculating the mass, which is determined by the formula taking into account the values of volume, temperature and density.

Therefore, accounting for the change in the mass of the oil product should be made taking into account the change in volume, as in the case of storage, and the density of the oil product should be determined at the level of discharge (filling) by one density sensor. This factor is especially important when taking an inventory of the fuel depot. Then the error between the data on the reception of oil in tanks, its presence in the tank farm and its release to consumers will be minimal.

The Alder-500 installation is notable for its low productivity, low reliability and maintainability, high price and the need for significant enclosed spaces.

The technical task is to increase the accuracy of measuring the mass and volume of oil in the processes of receiving and dispensing oil products from the tank, as well as reducing the complexity and price of installations.

The technical problem is achieved by the fact that the known dispensing installation, including a dispensing tank, connected by highways with dispensing columns equipped with counters for measuring the volume of oil product dispensing, a software system, is equipped with a densitometer installed on the connecting line at the outlet of the dispensing tank, and temperature measuring sensors located in each

dispensing column, the number of dispensing tanks is n> 1, for which either fuel dispensing tanks or simultaneously oil dispensing and oil dispensing tanks are used, as counters for measuring volume, use counters with a margin of permissible basic relative error when changing the volume of 0.08-0.15%, the software system is additionally equipped with information for recalculating the density by a standard value and calculating the density of the oil product at the outlet of each fuel distribution columns according to the temperature sensor of each column. As sensors for measuring temperature using low-inertia sensors for measuring temperature.

The utility model is illustrated in the drawing, where Fig. 1 shows a general installation diagram.

The fuel dispensing installation includes a fuel dispensing tank 1 for diesel fuel, an oil dispensing tank 2 for diesel oil, respectively connected by lines 3 and 4 to the fuel dispensers 5. At the outlet of the fuel dispensing tank 1, a density meter 6 is installed on line 3 to measure the density of oil entering the fuel dispensers 5 at the temperature of the line. At the outlet of the oil transfer tank 2, a density meter 7 is installed on the line 4 to measure the density of the oil entering the fuel dispensers 5 at the temperature of the line. Each fuel dispenser 5 is equipped with a temperature measurement sensor (not shown in the drawing) for measuring the temperature of the oil at each column and a volume measurement counter (not shown). Before installation in fuel dispensers, volume counters undergo selective selection. For mounting in fuel dispensers

columns use only volume measurement counters with a margin of allowable basic relative error when the volume changes 0.08-0.15%. The installation is connected to a software system (not shown in the drawing), which is additionally equipped with information for recalculating the size of the density taken from the densitometers 6 and 7 by a standard value and calculating the density of the oil product at the outlet of each fuel dispenser 5 according to the readings of the column temperature measuring sensor. As a temperature measurement sensor, a low-inertia temperature measurement sensor can be used.

The installation operates as follows.

When the petroleum product is dispensed from the fuel dispensing tank 1 or the oil dispensing tank 2 along the lines 3 and 4, respectively, the fuel enters the fuel dispensers 5. Density meters 6 and 7 measure the density of the oil product at the temperature (specific operating temperature) of the line. The data obtained are sent to the software system, where they are recorded until additional data on the volume and temperature of the oil product is obtained during the holidays. When petroleum products are dispensed to the consumer, volume measurement counters (error 0.08-0.15%) determine the consumption rate of the product being dispensed in the fuel dispenser, while at the same time the temperature of the oil product is measured using temperature sensors during its dispensing. The received data goes to the software system. The software, including density tables, recalculates the size of the density taken from densitometers 6 and 7 by a standard value (at a temperature of 20 ° C) and calculates the density of the product at the outlet of the fuel dispenser 5, taking into account the readings of the temperature measurement sensor of each column according to the tables translation

density at a certain temperature embedded in the software system. Thus, the size of the density of the oil is obtained when dispensed to the consumer with sufficiently high accuracy. Given the size of the volume of dispensed petroleum product, also determined with high accuracy, the mass of the dispensed petroleum product is calculated according to the well-known formula. The error in the consumption of the oil product is significantly reduced.

Thus, the proposed fuel-dispensing installation makes it possible to accurately and with a low error determine the flow rate of the oil product supplied to the consumer. By installing a single meter (densitometer) for measuring the density of the oil product, the cost of each installation is reduced (several times — installing a density meter in each fuel dispenser incurs significant economic costs, for example, in the Alder-500 installation, one densitometer is installed for each type fuel on each fuel dispenser tank and on each fuel dispenser, which increases the cost of installation). In the proposed installation, as mentioned above, one densitometer for each type of fuel for all columns is installed, which clearly indicates the lower cost of the proposed installation.

In addition, the proposed installation is quite compact, can be used not only when distributing, for example, diesel or other fuel, but also oil, for example, diesel.

Claims (2)

1. Fuel dispensing installation, including a dispensing tank connected by highways with dispensing columns equipped with counters for measuring the volume of oil product dispensing, a software system, characterized in that it is equipped with a densitometer installed on the connecting line at the outlet of the dispensing tank, and temperature measuring sensors located in each dispensing column, while the number of dispensing tanks is n> 1, for which either fuel dispenser is used in bulk or at the same time fuel dispensing and oil dispensing reservoirs, as counters for measuring volume, use counters with a margin of permissible basic relative error when changing the volume of 0.08-0.15%, and the software system is additionally equipped with information for recalculating the density to a standard value and calculating the density of the oil at the outlet of each dispensing column according to the readings of the temperature measuring sensor of each dispensing column. 2. Installation according to claim 1, characterized in that as inertia temperature sensors use low-inertia temperature measurement sensors.