RU116478U1 - DOUBLE BOTTOM GROUND VERTICAL RESERVOIR EQUIPPED WITH A COOLING MIXTURE OF VAPORS FOR OIL PRODUCTS WITH A COOLING MIXTURE - Google Patents

Abstract

An aboveground vertical tank with a double bottom, equipped with an oil vapor recovery unit with a cooling mixture, containing an additional steam pipeline system for removing vapors and a buried tank with low-octane oil product, characterized in that a steam line with shut-off valves is installed on the tank breathing valve body, connected to the buried tank, which is equipped with a receiving device for fuel vapors and an absorber filter, while the steam pipeline passes underground a cooling system, including a coil-type heat exchanger, a pipeline with valves, a pump and a container with a cooling mixture, it should be noted that the cooling mixture reduces the temperature in the heat exchanger by 7-9 ° C below the temperature of the earth's surface.

Description

The utility model relates to devices for receiving, storing and dispensing petroleum products and can be used in the petrochemical and other oil product supply industries.

The utility model is most applicable for the reception and storage of gasoline of various grades at terminals and tank farms equipped with large surface ground vertical steel tanks (PBC).

Air basin pollution at oil depots and terminals occurs when oil vapor is released during “large” and “small” tank breathing, improper installation of breathing equipment, and other reasons. Losses from "big" breaths are due to the displacement of the vapor-air mixture from the reservoir when receiving the oil product. At the same time, the volume of gas space decreases, which causes the breathing valve to operate. Losses from "small" breaths are caused by daily fluctuations in temperature and partial pressure of fuel vapor in the gas space of the tank. The temperature of petroleum products stored in ground tanks depends on the ambient temperature. In the summer, oil products in ground-based RCS are heated to 30 degrees Celsius or more. The gas boiling point is 35 degrees Celsius [1]. At this temperature, low-boiling gasoline fractions turn into steam and escape into the environment through a breathing valve.

Characteristic features in the operation of oil depots are the periodic delivery of oil products to tankers, the receipt of fuel from railway tanks and pipeline transport, as well as the long shelf life of fuel in tanks. This means significant losses from evaporation as a result of "small" breaths, as well as periodic losses from "large" breaths. Hydrocarbon emissions into the atmosphere during the evaporation of petroleum products from reservoirs are very large. This not only leads to fuel losses and air pollution, but also negatively affects public health.

Combating the loss of fuel from evaporation is becoming an important environmental and economic challenge.

Known vertical cylindrical steel tank for light petroleum products [2]. This tank has a bottom, a wall and a fixed roof. For receiving and dispensing petroleum products, reservoirs of this type have acceptance pipes. From the outside, valves are connected to them. In order to provide “small” and “large” tank breaths, there is a breathing valve. A metering hatch is installed on the roof of the tank, which serves to measure the level and take fuel samples.

Also on the tank there are monitoring and signaling devices (level gauges, samplers, level indicators, fire fighting devices) and other equipment (manhole, ventilation pipes, safety valves).

The disadvantages of this tank when receiving, storing and issuing petroleum products are:

1. Low efficiency of trapping vapors of oil products at oil depots, especially with "small" and "large" breathing tanks;

2. A high level of air pollution by vapors of oil products;

3. Large losses of oil products from evaporation;

4. The lack of a device to prevent leakage of fuel from the bottom of the tanks.

Also known installation of vapor recovery of petroleum products and water removal for ground horizontal steel tanks [3].

In this installation, the tank breathing valves are equipped with a common gas line with non-return valves and shut-off valves for venting oil vapors with “small” and “large” breaths, which is connected to an additional recessed horizontal steel tank with double walls R-5. At the same time, a tank with a capacity of 5000 liters is filled with a low-octane component, equipped with an activated carbon filter-absorber and a receiver of oil vapor with two partitions having cells of different diameters. Pipeline communications are welded to the bottom of the tanks with petroleum products to drain the water, equipped with valves and viewing devices. Pipeline communications are combined into a common line that connects to the double walls of the tank to capture the vapor.

Installation works as follows. With increasing temperature in the tanks, high-octane petroleum products begin to evaporate. Pairs of gasoline raise the plate of the poppet valve and enter the common gas line. In this line, a check valve opens under vapor pressure, and when the valve is open, the vapor enters the device for receiving oil vapor, equipped with two partitions with holes of various diameters. Vapors pass through partitions with holes of larger and smaller diameters in succession and enter a capture tank, in which water is poured into the interstitial space for cooling.

In this case, gaseous hydrocarbons as a result of lowering the temperature below 35 degrees and crushing the bubbles are absorbed by the low-octane component.

When carrying out "big" breaths associated with the intake of petroleum products, gasoline vapors similarly enter the capture tank. In this case, gaseous hydrocarbons as a result of crushing of the bubbles are 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.

In the process of vapor movement along the gas line, the non-return valve prevents them from entering neighboring tanks.

In winter, due to the low temperature, water is removed from the interstitial space of the capture tank.

The disadvantages of this installation are:

1. Low efficiency of trapping vapors of oil during "large" breaths.

2. Low efficiency of cooling vapors of high-octane oil products when passing through the pipeline to the receiving device.

3. The small length of the cooling pipe.

4. The lack of a device to prevent leakage of fuel from the bottom of the tanks.

Closest to the indicated problem is a ground-based vertical tank with a double bottom, equipped with a vapor recovery unit [4].

In this tank, the breathing valve is equipped with a pipeline with a valve for the removal of oil vapor during "small" and "large" breaths, which is connected to an additional horizontal recessed tank R-5. At the same time, the pipeline underground is located in a larger-diameter refrigeration pipe, equipped with valves and filled with water (coolant in winter). The P-5 tank is filled with a low-octane component, equipped with an activated carbon filter-absorber and a receiver of oil vapor.

The technical device operates as follows. The oil enters the reservoir through the intake pipe. In this case, the fuel level begins to increase, and accordingly the volume of the steam space decreases. In order to catch the vapors during “big” breaths, the breathing valve opens, the non-return valve and through the pipeline the vapors enter the reservoir with a low-octane component equipped with a receiving device. At the same time, part of the gaseous hydrocarbons as a result of crushing the bubbles by two partitions with holes of different diameters is absorbed by the low-octane oil product. The insoluble part of the gaseous hydrocarbons at the outlet of the tank is captured by the filter-absorber.

With "small" breaths associated with temperature changes, with increasing pressure, the breathing valve also opens and oil vapor through the pipe through a receiving device with partitions, enters the reservoir with a low-octane component.

At the same time, most of the vapor is converted into liquid due to cooling in the underground section of the pipeline located in the refrigerator’s pipeline.

The disadvantages of this tank with the installation of vapor recovery are:

1. Low efficiency of trapping vapors of oil at "big" breaths;

2. Lack of heat exchanger with pumped coolant;

3. Low efficiency of cooling vapors of high-octane oil products when passing through the pipeline to the receiving device;

4. The absence of a significant decrease in the temperature of the coolant compared with the temperature of the earth's surface, which does not allow a pair of oil products to completely translate into a liquid state

The proposed utility model allows us to solve the problem of increasing the efficiency of trapping vapors of oil products stored in vertical ground tanks, when fumes occur mainly due to changes in temperature (“small” breaths), as well as in connection with the intake of fuel (“large” breaths). "Big" breaths occur with a certain frequency associated with the intake of fuels and lubricants.

The solution to this problem is achieved by the fact that a steam line with shutoff valves is installed on the body of the tank’s breathing valve, connected to a buried tank, which is equipped with a receiving device for fuel vapor and a filter with an absorber, while the steam line under the ground passes a cooling system including a coil-type heat exchanger, a pipeline with valves, a pump and a container with a cooling mixture, it should be noted that the cooling mixture reduces the temperature in the heat exchanger by 7-9 degrees Celsius below Temperature earth's surface.

These signs are essential for solving the utility model problem, since the efficiency of collecting oil vapor in ground tanks during storage and reception of fuel is significantly increased, and the environmental situation in the areas where oil depots are located improves.

The essence of the utility model is illustrated by drawings (Fig. 1, Fig. 2, Fig. 3), which depict: sections of a tank with a vapor recovery unit, a breathing valve with an additional steam line, and a heat exchanger with a cooling system.

The proposed tank 1, having a receiving and distributing nozzles 2, a pipe for receiving and dispensing oil products 3, valves 4, light and metering hatches 5, 6, a ventilation pipe 7, an overpressure breathing valve 8, a manhole 9, a working pressure breathing valve 10, an additional steam line 11 with a non-return valve 12 and a valve 13 is equipped, which is connected to a buried horizontal steel tank 14. The tank is equipped with an activated carbon filter-absorber 15 and a device for receiving oil vapor ktv 16, which has two partitions with holes of different diameters 17, 18 for crushing vapor bubbles. The recessed tank is half filled with the low-octane component 19.

An additional steam line under the earth's surface 20 passes a coil-type heat exchanger 21 with a cooling mixture 22, 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. This is sufficient to convert gasoline vapors to a liquid state.

The cooling mixture from the tank 23 is supplied to the heat exchanger through the cooling system pipe 24, equipped with valves 25 using the pump 26. Water is supplied to the cooling mixture tank from the fire pipe 27. The heat exchanger is equipped with elbows 28 and a drain cock 29 to drain the cooling mixture. The cooling system with a heat exchanger, pump and tank is located underground in the technological well 30.

The vertical steel tank is mounted with a double bottom 31 with stiffeners 32. The space between the bottoms is equipped with a device 33 with a valve 34 for checking the level of gas contamination with oil products.

The utility model works as follows. Through the intake pipe 3, the oil enters the tank 1. At the same time, the level of fuel 35 begins to increase, and accordingly the volume of the vapor space 36 decreases. Excessive vapor pressure is created in the tank. In order to catch the vapors during “big” breaths, the breathing valve 10 opens, the non-return valve 12 and through the steam line 11 connected to the additional tank 14, equipped with a receiving device 16, the pairs enter the heat exchanger 21 with the pumped cooling mixture 22, which is supplied from the tank 23 through the pipeline cooling system 24 using a pump 26. The cooling mixture creates a temperature in the heat exchanger 7-9 degrees Celsius below the temperature of the earth's surface.

In this case, the bulk 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 with holes of various diameters 17, 18 and absorbed by the low-octane oil product 19. The insoluble part of the gaseous hydrocarbons at the outlet of the tank is trapped by the filter - absorber 15. After the end of the reception of petroleum products into the tank, the pump of the cooling system is turned off.

With "small" breaths associated with temperature changes, with increasing pressure in the vapor space of the tank, the breathing valve 10 also opens and oil vapor passes through the steam line 11 through a receiver 16 with baffles 17, 18 to the tank 14 with a low-octane component 19. The pump of the cooling system with these breaths, it is advisable to include at temperatures above 30 degrees Celsius.

During the period of “small” breaths, vapors turn into liquid due to cooling in the heat exchanger.

In the event of a fuel leak through the bottom of the tank, the oil product will remain in the tank due to the second bottom 31. The gas contamination of the space between the bottoms is controlled using a device 33 equipped with a valve 34.

Literature

1. A.S.Safonov et al. Automotive fuels. Chemotology. Operational properties. Range. SPb .: NPIKTS, 2002.

2. B.C. Yakovlev. Storage of petroleum products. Problems of environmental protection - M .: Chemistry, 1987.

3. K.R. Kundrotas, Yu.A. Matveev and others. Patent for utility model No. 84253. Installation for vapor recovery of petroleum products and water removal for ground horizontal steel tanks.

4. Yu.A. Matveev, S.M. Anoprienko. Utility Model Patent No. 101023. A vertical bottom tank with a double bottom equipped with a vapor recovery unit.

5. V.G. Kovalenko. Ecological safety in oil products supply systems and automobile transport. M .: LitNefteGaz, 2004.

Claims (1)

A vertical ground tank with a double bottom, equipped with an oil vapor vapor recovery unit with a cooling mixture, containing an additional steam system for venting vapors and a recessed tank with low-octane oil product, characterized in that a steam pipe with shutoff valves connected to the recessed tank is installed on the tank’s breathing valve body, which is equipped with a receiving device for fuel vapor and a filter with an absorber, while the steam pipe underground passes through the system in cooling, comprising a coil type heat exchanger, a conduit with valves, pump and a container with a cooling mixture, it should be noted that the cooling mixture lowers the temperature in the heat exchanger at 7-9 ° C below the earth's surface temperature.