RU141280U1 - INSTALLATION OF COLLECTING VAPORS OF OIL PRODUCTS WITH PERIODIC OPERATION OF THE REFRIGERATING UNIT AT PETROL FILLING STATIONS - Google Patents

Abstract

The utility model relates to a device for trapping vapors of oil products and can be used at gas stations or gas stations.

The solution to this problem is achieved by the fact that the breathing valves of the tanks at the gas station are equipped with a piping system connected to the main steam line connected to a recessed tank with a low-octane component, while the main steam pipe passes through a heat exchanger connected to the refrigeration unit, as well as the fact that the vapors from the car tanks the unit is pumped out through a two-channel dispensing sleeve and a section of the steam line into a separate tank for collecting vapors, equipped with a manometer designed to be switched on using refrigeration unit relay, and non-return valves with different opening pressures, while oil vapor accumulates in the tank and periodically through the high-pressure check valve enter the main steam line passing through the heat exchanger with the set temperature regime, and then into the tank with a low-octane component for additional absorption.

The utility model works as follows. Through the drain device, the oil enters the tank. In this case, the fuel level begins to increase, and accordingly the volume of the steam space decreases. The operator turns on the refrigeration unit. With increasing pressure, the reservoir breathing valve plate and the vapor rise through an open pipeline system, the non-return valve enters the main pipeline connected to an additional tank equipped with a receiving device. Vapors pass through a heat exchanger. In this case, the main part of gaseous hydrocarbons as a result of cooling in the heat exchanger turns into a liquid state, and vapors that have not passed into a liquid are stratified by two partitions with holes of various diameters and absorbed by the low-octane component. The insoluble part of the gaseous hydrocarbons at the outlet of the tank through the breathing valve is captured by the filter-absorber. Vapors from car tanks are refilled with oil product during refueling. On a two-channel sleeve, with the help of the unit, through the section of the steam line and the low-pressure check valve, the vapor enters the vapor collection tank. Upon reaching a certain vapor pressure, the manometer installed on the tank through the communication line and the corresponding relay includes a refrigeration unit to establish a given temperature regime. Vapors accumulate in the tank to the response pressure of the overpressure check valve. When the operating pressure of the non-return valve is reached, the corresponding manometer through the communication line and the corresponding relay includes an electric motor to rotate the shaft with centrifugal wheels in order to spray the low-octane component throughout the volume of the tank. At the same time, through the communication line, the corresponding relay switches on the electric motor to open the valve.

After opening the non-return valve of high pressure and the valve, the pairs of oil products through the steam pipe enter the heat exchanger with the set temperature regime. Then the mixture of vapors with liquid oil enters the receiving device and into the tank with a rotating shaft and centrifugal wheels. In the tank, oil vapor is absorbed by the low-octane component sprinkled throughout the volume. After completing all operations, the operator turns off the refrigeration unit, an electric motor for rotating the shaft. Then closes the valve.

Periodic operation of a refrigerator with a set temperature regime, an electric motor for rotating the shaft significantly reduce energy consumption, and also increase the efficiency of trapping oil vapor at gas stations.

Description

The proposed utility model relates to devices for trapping vapors of oil products and can be used in the petrochemical and other oil product supply industries.

The utility model is most applicable when issuing and receiving automobile gasolines of various brands at gas stations. Air pool pollution at gas stations occurs when oil vapor is released during “large” and “small” tank breathing, fuel is dispensed into tank cars, improper installation of breathing equipment, and other reasons. Losses from "big breaths" are due to the displacement of the vapor-air mixture (PVA) from the reservoir when receiving the oil product. In this case, the volume of gas space decreases and the breathing valve is activated. Losses from "small" breaths are caused by daily fluctuations in temperature and partial pressure of fuel vapor (mainly gasoline) in the gas space of the tank. In modern conditions, when gas stations are equipped with underground tanks, losses from "small" breaths are negligible.

Characteristic features in the operation of gas stations are the issuance of small doses of a large amount of oil into tank cars. This means significant evaporation loss. Hydrocarbon emissions into the atmosphere during the evaporation of petroleum products from tanks, as well as during refueling in the fuel tanks of cars are very large. This not only leads to fuel losses, but also negatively affects public health. Given that modern gas stations are equipped with underground reservoirs that minimize daily temperature fluctuations, combating fuel losses from “large” breathing reservoirs and when refueling petroleum products in tank cars become an important environmental and economic task.

A device for capturing a vapor-air mixture from tanks of refueling vehicles [V.V. Anferov, V.G. Kovalenko, A.N. Rementsov. Technical equipment and personnel in oil products supply systems. Tutorial. M: MADI. 2006]. In this device, the air-vapor mixture from the tanks of the cars is sucked off using an automatic crane with the removal of oil vapor through the sleeve by a special column unit and is pumped through the pipeline into an injection device located in the tank, in which the fuel has a lower octane rating. The sleeve for collecting oil vapor is a two-channel sleeve in which the vapor is sucked through an internal hose with a small hole [V.G. Kovalenko, A.S. Safonov, A.I. Ushakov, V. Shergalis. Gas stations. Equipment, operation, safety. St. Petersburg, NPIKTS. 2003.]. The injection device is a vapor-liquid jet ejector. When the vapor-air mixture is injected into it, it leaves the injector nozzle at a high speed and creates a reduced pressure in the end space of the injector. Through the holes in the flange of the injector, liquid reservoir oil is sucked in and pumped into the internal space of the divider, while mixing with the vapor-air mixture, dissecting into small particles, and then scattering into the reservoir space. The process of crushing into small particles of a vapor-air mixture and liquid increases the contact surface of two phases of steam and liquid, which increases the rate of condensation of oil vapor and allows them to condense up to 80%. The rest of the mixture enters the vapor-air space of the tank.

The disadvantages of this device are:

1. The lack of the ability to capture vapors of oil from tanks.

2. Lack of cooling system and incomplete condensation of oil vapor.

3. Mixing fuels with different octane numbers.

4. The complexity of the device injector and the selection of balanced costs of petroleum products and their vapors.

A known installation of vapor recovery of petroleum products from automobile tanks and tanks using a cooling mixture [Yu.A. Matveev et al. Utility Model Patent No. 122994 of December 20, 2012. Installation for vapor recovery of petroleum products from automobile tanks and tanks using a cooling mixture].

In this installation, a removable device is mounted on the neck of a car tank on a flexible sleeve, which is connected to a section of the steam pipeline of a loading and unloading trestle. A compressor for pumping oil vapor and a non-return valve are installed on the steam pipeline section. The section of the steam pipeline of the loading and unloading trestle is connected to the main steam pipeline with a non-return valve and a valve that connects to a recessed horizontal steel tank. The tank is equipped with an activated carbon filter-absorber and a device for receiving oil vapor. The recessed tank is half filled with a low-octane component in the quality of which diesel fuel is used. The main steam line under the earth's surface is a coil-type heat exchanger with a cooling mixture representing a 15% aqueous solution of sodium carbonate. This cooling mixture is economically feasible, since it has a low cost and high efficiency, which allows to reduce the temperature in the heat exchanger to 7-9 degrees Celsius relative to the temperature of the earth's surface. The cooling mixture from the tank is fed to the heat exchanger through a cooling system pipe equipped with valves using a pump. Water in the tank for the cooling mixture is supplied from the fire line. The heat exchanger is equipped with elbows and a drain valve for draining the cooling mixture. The cooling system with heat exchanger, pump and tank is located underground in the technological well.

Installation works as follows. Through the inlet pipe of the automobile tank, the oil enters the tanker. In this case, the fuel level begins to increase, and accordingly the volume of the steam space decreases. An excessive vapor pressure is created in the tank. At the same time, the vapors along the flexible hose enter the section of the steam line and are pumped out with the help of the compressor through the check valve open under the compressor pressure into the main steam line connected to the additional tank equipped with a receiving device. Vapors pass through a heat exchanger with a pumped cooling mixture, which is supplied from the tank through the pipeline of the cooling system using a pump. In this case, the main part of gaseous hydrocarbons as a result of cooling in the heat exchanger turns into a liquid state, and vapors that do not pass into the liquid are stratified by two partitions with holes of various diameters and absorbed by the low-octane component. The insoluble part of the gaseous hydrocarbons at the outlet of the tank is captured by the filter-absorber.

During “large” and “small” breathing with increasing pressure of the vapor space of the tank, which is equipped with breathing valves of working and high pressure, the breathing valve of working pressure opens, and the vapor of oil products through the steam line enter the heat exchanger with the pumped cooling mixture, which is supplied from the tank through the pipeline cooling system using a pump.

After the heat exchanger, a mixture of vapors with liquid oil enters the receiver and into the reservoir with the low-octane component. The check valve prevents the entry of oil vapor from the tank into the section of the steam pipe to catch fuel vapor from the tank car.

The disadvantages of this installation are:

1. The lack of the ability to capture vapors from the tanks of cars.

2. Low efficiency of the absorption of oil vapor by the low-octane component.

3. The complexity of the device system using a cooling mixture. Insufficient action time of the cooling mixture.

Known absorption installation for vapor recovery ASUR-PB [V.G. Kovalenko Ecological safety in oil products supply systems and automobile transport. M .: LitNefteGaz, 2004.]. This unit is designed to capture and recover vapors of oil products at gas stations, oil depots, oil refineries. The installation is based on the principle of absorption - the absorption of hydrocarbons by a liquid absorbent. Diesel fuel is used as an absorbent. The installation consists of two units: absorption and refrigeration, as well as a control panel. In the absorption unit, vapor is captured by the cooled absorbent. The refrigeration unit is designed to cool the coolant and supply it to the absorption unit. The control panel provides automatic installation. Inside the absorption block on the bearings, a rotor is installed, which is a shaft with bearing discs mounted on it. Thin ring contact disks are installed on each carrier disk so that a certain gap is maintained between them. In the upper part of the absorption block there are inlet and outlet nozzles for vapors, in the lower for absorbent. The housing of the absorption unit is filled with absorbent material to a certain level.

Installation works as follows. When the rotor rotates on the surface of the contact disks immersed in diesel fuel, a thin absorbent film is formed. Air contaminated with oil vapor from tanks, automobile or railway tanks enters the absorption block through the inlet pipe, passes through the gaps between the contact disks, is cleaned, giving hydrocarbons to the absorbent, and leaves the absorption block through the outlet pipe. Absorbent flows towards the flow of the vapor-air mixture along the bottom of the block. The rotation of the rotor, partially immersed in diesel fuel, provides a constant replacement of the absorbent film. To reduce the temperature of the absorbent, the installation includes a refrigeration unit, which is performed as a separate unit. The decrease in temperature of the absorbent occurs in the heat exchanger.

To capture the vapors from the tanks of cars using the ASUR-PB installation, the fuel dispensers are equipped with units for collecting oil vapor from the necks of the fuel tanks of automobiles. These are special dispensing taps with additional valves for collecting vapors, two-channel dispensing hoses for venting vapors into reservoirs, a unit for supplying vapors to the reservoir, special valves that balance fuel and vapor consumption. When refueling tanks of machines, the installation works as follows. Oil product vapors from car tanks are pumped out by a column unit through a dispensing tap, a two-channel dispensing sleeve, a steam line to the tank from which the cars are refueling.

The disadvantages of this installation are:

1. The lack of efficiency in catching vapors from the tanks of cars, since it is quite difficult to balance the costs of issuing fuel to the tanks and feeding the vapor into the tank.

2. The complexity and high cost of installation.

3. Large electric power consumption by refrigeration and absorption units, as well as a unit for supplying vapors from car tanks.

4. High consumption of absorbent.

Also known installation of vapor recovery of oil products from tanks and tanks of cars at gas stations [Matveev Yu.A., Kuznetsov VA, Butuzov AA, Mulgachev A.Yu. Utility Model Patent No. 131479 of 08/20/2013. Installation for the capture of vapors of petroleum products from tanks and tanks of cars at gas stations].

In this installation, a common pipeline line with a gate valve and a non-return valve, which is connected to the main steam line connected to a recessed horizontal steel tank, is horizontally installed on a tank having a fuel dispensing device, a drain device, a breathing valve, and additionally on a breathing valve body. The tank is equipped with a breathing valve, an activated carbon filter-absorber and a device for receiving oil vapor, which has two partitions with openings of different diameters for crushing vapor bubbles. The recessed tank is half filled with a low-octane component.

The main steam line below the earth's surface is a coil-type heat exchanger with a cooling mixture. The cooling mixture from the tank is fed to the heat exchanger through a cooling system pipe equipped with valves using a pump. Water in the tank for the cooling mixture is supplied from the fire line. The heat exchanger is equipped with elbows and a drain valve for draining the cooling mixture. The cooling system with heat exchanger, pump and tank is located underground in the technological well.

Also, the dispensing valve, which is inserted into the fuel tank of the car, is equipped with a two-channel dispensing sleeve connected to the fuel dispenser. Vapors of petroleum products through the hose are fed through the unit to the section of the steam line, and then through the low pressure check valve to a separate tank for collecting vapors. Vapors of oil products pumped out of the tanks of the machines, due to the supply of the unit, accumulate in the tank up to a certain pressure, for which the high-pressure check valve is designed. Vapor pressure is recorded by a manometer, which is connected by a communication line to the relay. The relay includes an electric motor connected by means of a coupling to a shaft on which centrifugal wheels are located. The shaft is mounted on bearings.

Installation works as follows. Through the drain device, the oil enters the tank. In this case, the fuel level begins to increase, and accordingly the volume of the steam space decreases. With increasing pressure, the reservoir breathing valve plate and the vapor rise through an open pipeline system, the non-return valve enters the main pipeline connected to an additional tank equipped with a receiving device. Vapors pass through a heat exchanger with a pumped cooling mixture, which is supplied from the tank through the pipeline of the cooling system using a pump.

In this case, the main part of gaseous hydrocarbons as a result of cooling in the heat exchanger turns into a liquid state, and vapors that have not passed into a liquid are stratified by two partitions with holes of various diameters and absorbed by the low-octane component. The insoluble part of the gaseous hydrocarbons at the outlet of the tank through the breathing valve is captured by the filter-absorber.

Vapors from car tanks are refilled with oil product during refueling. On a two-channel sleeve, with the help of the unit, through the section of the steam line and the low-pressure check valve, the vapor enters the vapor collection tank. Vapors accumulate in this reservoir to the response pressure of the overpressure check valve. Upon reaching the response pressure of the non-return valve, the manometer through the communication line and the relay includes an electric motor that starts to rotate the shaft with centrifugal wheels to spray the low-octane component throughout the tank. Also, through the communication line, the relay includes a pump for supplying the cooling mixture through the heat exchanger.

After the high pressure check valve is opened, oil product vapors enter the heat exchanger with the pumped cooling mixture through the steam line. Then the mixture of vapors with liquid oil enters the receiving device and into the tank with a rotating shaft and centrifugal wheels. In the tank, oil vapor is absorbed by the low-octane component sprinkled throughout the volume. After closing the high-pressure check valve, the operator opens the valve, and the oil vapor due to the increased pressure similarly enters the tank and is absorbed by the low-octane component. After completing all operations, the operator manually turns off the electric motor and the pump for supplying the cooling mixture.

The proposed utility model allows us to solve the problem of efficiently collecting oil vapor from tanks of refueling machines and from underground tanks, in which the main fumes occur in connection with the intake of fuel (“big” breaths). Also, the consumption of absorbent material, the consumed electric power of the installation are reduced, and there is no need to use a cooling mixture.

The solution to this problem is achieved by the fact that the breathing valves of the tanks at the gas station are equipped with a piping system connected to the main steam line connected to a recessed tank with a low-octane component, while the main steam pipe passes through a heat exchanger connected to the refrigeration unit, as well as the fact that the vapors from the car tanks the unit is pumped out through a two-channel dispensing sleeve and a section of the steam line into a separate tank for collecting vapors, equipped with a manometer designed to be switched on using refrigeration unit relay, and non-return valves with different opening pressures, while oil vapor accumulates in the tank and periodically through the high-pressure check valve enter the main steam line passing through the heat exchanger with the set temperature regime, and then into the tank with a low-octane component for additional absorption.

These signs are essential for solving the utility model problem, since the efficiency of oil vapor recovery during refueling of machine tanks and from underground tanks is increased, the reliability of the operation of the installation is increased, and the electrical power consumption of the installation is significantly reduced.

The essence of the utility model is illustrated by drawings (figure 1, figure 2), which depict: rear view of the car, sections of the installation and the underground reservoir. The proposed tank 1 having a device for dispensing fuel 2, a drain device 3, a breathing valve 4, additionally on the housing of the breathing valve, horizontally installs a common pipe line 5 with a valve 6 and a check valve 7, which is connected to the main steam line 8 connected to a recessed horizontal steel tank 9. The tank 9 is equipped with a breathing valve 4, an activated charcoal filter-absorber 10 and a device for receiving oil vapor 11, which has two partitions with about with holes of various diameters 12.13 for crushing vapor bubbles. The recessed tank is half filled with low-octane component 14, which is used as diesel fuel.

The main steam line beneath the earth's surface 15 passes a coil-type heat exchanger 16. The heat exchanger is equipped with cooling lines 17 and is connected to the refrigeration unit 18. For the purpose of switching on and off, the refrigeration unit is connected via a communication line 19 to the corresponding relay 20 and is located underground in the technological well 21.

Also, the dispensing valve 22, which is inserted into the fuel tank of the car 23, is equipped with a two-channel dispensing sleeve 24 connected to the fuel dispensing column 25. Oil product vapors are fed through the sleeve 24 to the section of the steam line 27 through the sleeve 26, and then through a low pressure check valve 28 to a separate vapor collection tank 29. The vapor collection tank is equipped with an appropriate pressure gauge 30. The pressure gauge 30 is connected via a communication line 19 to a corresponding relay 20 to turn on the refrigeration unit 18. Oil vapor evacuated from the tanks of the machines, due to the supply of the unit 26, they accumulate in the tank 29 to a certain pressure for which the high-pressure check valve 31 is designed. The vapor pressure is registered by the corresponding pressure gauge 30, which is connected via a communication line 19 to the corresponding relay 20. The relay includes an electric motor 32 connected to using the coupling 33 with a shaft 34, on which the centrifugal wheels 35 are located. The shaft 34 is mounted on the bearing bearings 36. Also, the relay 20 is connected by a communication line 19 to the corresponding motor 32 to open the valve 37.

The utility model works as follows. Through the drain device 3, the oil enters the tank 1. At the same time, the level of fuel 38 begins to increase, and accordingly, the volume of the vapor space 39 decreases. The operator turns on the refrigeration unit 18. With increasing pressure, the plate of the breathing valve 4 of the tank 1 rises and the vapors move through the open pipeline system 5, the check valve 7 enters the main steam line 8 connected to the additional tank 9 equipped with a receiving device 11. The vapors pass through the heat exchanger 16.

In this case, the main part of the gaseous hydrocarbons as a result of cooling in the heat exchanger becomes liquid, and the vapors that have not passed into the liquid are stratified by two partitions 12,13 with holes of various diameters and are absorbed by the low-octane component 14. The insoluble part of the gaseous hydrocarbons at the outlet of the tank 9 through the breathing valve 4 is captured by the filter-absorber 10. The vapor valve 31 prevents the entry of vapor into the tank 29.

Vapors from car tanks are refilled with oil product during refueling. On a two-channel sleeve 24, with the help of the unit 26, through the section of the steam line 27 and the low pressure check valve 28, the steam enters the reservoir for collecting vapors 29. When a certain vapor pressure is reached, the corresponding pressure gauge 30 installed on the reservoir 29 through the communication line 19 and the corresponding relay 20 includes a refrigeration block 18 for establishing a given temperature, which should be in the range from minus 5 to minus 10 degrees Celsius. In the tank 29, the pairs accumulate until the response pressure of the overpressure check valve 31. When the response pressure of the check valve is reached, the corresponding pressure gauge 30 through the communication line 19 and the corresponding relay 20 includes an electric motor 32, for rotation of the shaft 34 with centrifugal wheels 35 to spray the low-octane component 14 the entire volume of the tank 9. At the same time, through the communication line 19, the corresponding relay 20 turns on the corresponding motor 32 to open the valve 37.

After opening the check valve high pressure 31 and the valve 37, a pair of petroleum products through the steam line 8 enter the heat exchanger 16 with a set temperature. Then the mixture of vapors with liquid oil enters the receiving device 11 and into the reservoir 9 with a rotating shaft 34 and centrifugal wheels 35. In the reservoir 9, the vapor of the oil is absorbed by the low-octane component sprayed throughout the volume 14. After the completion of all operations, the operator turns off the refrigeration unit 18, the electric motor 32 to rotate the shaft 34, then closes the valve 37.

Periodic operation of a refrigerator with a set temperature regime, an electric motor for rotating the shaft significantly reduce energy consumption, and also increase the efficiency of trapping oil vapor at gas stations.

Claims (1)

Installation of vapor recovery of petroleum products with periodic operation of the refrigeration unit at gas stations, characterized in that the breathing valves of the tanks at the gas station are equipped with a piping system connected to the main steam line connected to a recessed tank with a low-octane component, while the main steam line passes through a heat exchanger connected to the refrigeration unit, as well as the fact that the pairs from the tanks of the machines are pumped through a two-channel dispensing sleeve and a section of the steam pipe into a separate a vapor collection tank equipped with a manometer designed to be switched on using the relay of the refrigeration unit and non-return valves with different opening pressures, while oil vapor accumulates in the tank and periodically through the high pressure check valve enter the main steam pipe passing through the heat exchanger with the set temperature mode, and then into the tank with a low octane component for additional absorption.

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