RU182746U1 - Respiratory Respiratory System - Google Patents

Abstract

The respiratory system is designed for storage tanks for volatile liquids, in particular oil and petroleum products. The system provides a reduction in the level of water cut of the oil product in the tank and a reduction in the loss of volatile liquid (oil, oil) when stored in a metal tank by supplying dried air to the breathing valve of the tank and venting air with vapors of volatile liquid from the same breathing valve through the proposed supply device air exhaust, made in the form of an annular duct communicated with the surrounding atmosphere. The annular duct is formed by two concentrically arranged shells, while the inner shell is the inner wall of the annular cavity and at the same time limits the inner cavity of the annular duct in which the breathing valve is located, and the outer shell is the outer wall of the annular cavity. Slots are made on the inner casing, communicating the annular cavity of the annular duct, isolated from the surrounding atmosphere, with its internal cavity, and the duct is connected to the outer casing, communicating the annular cavity of the duct with air intake, a feed pump, a condenser-condenser, a pump and a fridge-condenser of vapor of a volatile liquid.

Description

The utility model relates to the equipment of reservoirs for storing volatile liquids, in particular oil and oil products.

A device is known for storing and reducing oil losses (RU 2328430, 2008), which is equipped with a corrugated oil-resistant metal-polymer chamber located inside the metal tank and exiting through the dome of the tank with an air duct and gradually changing in volume as the tank is filled with oil or pumped out of the tank a pump for an oil inlet or oil outlet pipe, arranged on top of each other and interconnected by a metal pipe with a water pump, metal gas collection an icom with an aqueous solution of sodium chloride and a collector of an aqueous solution of sodium chloride attached to the top of the lid of the aqueous solution of sodium chloride by a metal hatch and a nozzle with a tap connected to the upper part of the gas collector body with a metal exhaust pipe connected to the dome of the tank and to the upper part of the housing the gas collector with a metal gas supply pipe with a tap located at the bottom of the tank with a metal cone-shaped shower connected to the tank shower and to the upper side hand side of the housing of the gas plenum metal gas inlet tube with a tap.

Known respiratory system of a reservoir for volatile liquids (patent RU 2181336, 2002), including a condenser connected to the reservoir with a gas collector fixed therein, an adsorber with sorbent granules mounted on a condenser, a heat exchanger in the form of a flat battery of thermocouples located between the condenser and the adsorber and facing cold junctions to the condenser, and hot to the adsorber, a pipe for connecting the condenser with the adsorber and the atmosphere, while the gas collector is made of highly porous of permeable cellular material, the system is equipped with plates, one of which is located on the side of hot junctions of thermocouples, has ribbing and is made of highly porous permeable cellular material, and the other is on the side of cold junctions of thermocouples, made of highly porous permeable cellular material and placed on the gas collector.

A known installation for vapor recovery of petroleum products from automobile tanks and tanks using a cooling mixture (patent RU 122994 U1), in which a removable device is mounted on a neck of the tank on a flexible sleeve. The oil enters the tanker through the tank’s inlet pipe. 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, and the vapor flows through a flexible hose into the section of the steam line and is pumped out with the help of the compressor through the check valve open under the compressor pressure into the main steam line 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 becomes liquid, 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 oil product.

The closest analogue of the utility model is the installation for vapor recovery of petroleum products with an additional reservoir for collecting vapors and a cooling system for ground vertical steel tanks (patent RU 142402 U1). In this installation, a steam line is installed on the tank’s breathing valve body, connected to a recessed tank, which is equipped with a receiving device for fuel vapor and a shaft for rotating centrifugal wheels, while the vapor from the tank is pumped to an additional vapor collection tank equipped with non-return valves with different opening pressures , as well as the fact that under the pressure of the compressor, oil vapor accumulates in an additional tank and periodically through a return valve the high pressure pan and the corresponding valve enter the main steam line with a cooling system, including a heat exchanger, a pump and a container with a cooling mixture, and then into a buried tank for additional vapor absorption.

Analogs known from the prior art, including the closest analogue, are complex in construction and also require significant refinement of existing reservoirs for storing flammable liquids if it is necessary to install the reservoir breathing system on an already mounted reservoir.

It is known that evaporation during the filling of the tank during storage or pumping of oil from the tank leads to a decrease in the amount of oil and impairs its quality.

The following evaporation losses are distinguished:

1) when filling tanks (“big breaths”);

2) during stationary storage (“small breaths”);

3) when pumping oil from the tank due to saturation of the gas space (“reverse exhalation”).

The technical problem that is solved by the claimed utility model is the preservation of the quality of the oil product by preparing the atmospheric air before it is supplied to the breathing valve of the tank by draining it, that is, removing excess moisture from the air entering the tank when pumping the oil while simplifying the design of the device.

In humid atmospheric air, when the humidity is close to 70-100% - this usually happens in the summer months or during precipitation (rain) in a 5000 m ³ tank when it is emptied, the moist air coming from outside can add about 50 liters of water, t. e. 1 liter of water per 100 m ³ volume of air, while water partially condenses on the walls of the tank and in the fuel, worsening its quality. The mechanisms of watering fuel in tanks from incoming air are described in the scientific literature [K.V. Rybakov, E.N. Zhuldybin, V.P. Kovalenko. "Dehydration of aviation fuels and lubricants", M, Transport, 1979, 181 s; Kovalenko V.P., Ilyinsky A.A. Fundamentals of the technique for cleaning liquids from mechanical impurities. - M .: Chemistry, 1982. - 340 s]

The essence of the utility model, which allows to reduce the level of water cut in the oil product stored in a metal tank by preparing the air - by drying it before it is supplied to the breathing valve of the tank, consists in preparing the air - by draining it before feeding it into the breathing valve of the tank, and for supplying dried air, a device for supplying and discharging air in the form of an annular duct is used, which is formed by two concentrically arranged shells, for example cylindrical (or other shape), tained at a distance from each other and insulated from the atmosphere of the upper and lower bases, both sealingly connected to the shells, between the shells to form an annular cavity isolated from the atmosphere. The inner shell is made with slots and limits the inner cavity of the annular duct into which the breathing valve is located, the inner cavity of the annular duct communicating with the surrounding atmosphere, and the valve is installed at a distance from the inner shell, forming an “atmospheric gap”, i.e. a gap connecting with the surrounding atmosphere between the inner surface of the annular duct (the shell with slots) and the breathing valve. The design of the annular duct provides the supply of prepared, dried air to the breathing valve. In the claimed utility model, an air preparation system is provided, which includes a unit for purifying air from water and dust particles, an air filter and a refrigerator-condenser of air moisture, providing a constant low humidity, regardless of the absolute humidity of the ambient air surrounding the tank with volatile liquid, mainly with oil. For cooling and drying of atmospheric air, in particular, an industrial air conditioner can be used, which is located outside the tank.

The technical result from the use of the claimed utility model is to reduce the water cut of the oil product in the tank by pre-treating the air with "large" and "small" breaths by supplying dry (dried) air to the breathing valve of the tank and venting air with vapor of easily volatile liquid from the same breathing valve through the device supply / exhaust air (annular duct), in communication with the surrounding atmosphere.

The specified technical result is achieved due to the fact that the breathing valve in communication with the internal volume of the tank is also in communication with the preliminary air preparation system through an “atmospheric gap” between the breathing valve and the annular duct. For this purpose, slots are made on the inner ring of the annular duct, communicating the “atmospheric gap” with the inner cavity of the annular duct, and an air supply / exhaust duct is connected to the outer shell, communicating the annular duct with air intake through the moisture condenser cooler located in front of the breathing valve , and with a fridge-condenser of vaporized liquid located behind the breathing valve, while the annular duct is installed with a gap in relation south to the breathing valve with the creation of an air cavity, an “atmospheric gap” between the inner shell and the breathing valve, the air cavity being open into the surrounding atmosphere from above and below.

The claimed respiratory system of the tank creates the conditions for reducing the level of water cut of the oil in the tank and protecting the volatile liquid from the negative effects of changes in the absolute humidity of the ambient air and maintains the internal pressure in the tank, allows you to take air away from the tank, clean and extract excess moisture from it and then feed into the tank, creating an “atmospheric gap” in the suction zone from the prepared dried air g vent valve, which increases the reliability of the air supply-discharge system eliminates the need for a complicated control system dehumidified air flow due to the fact that the presence of "Outside the gap" controls the air flow at the vent valve on the suction. The air flow through the breathing valve is determined using the control unit, which sets the air flow depending on the current flow rate of the fuel pumps, which either fill the tank or empty it, while the flow of dried air when emptying the tank should exceed the calculated value, preferably by about 10 % to compensate for possible losses that may occur in the "atmospheric gap". An additional advantage of the claimed utility model is that the installation of an air preparation device does not require intervention in the design of existing and operating tanks.

The utility model is illustrated by drawings, which depict

In FIG. 1 is a diagram of a respiratory system of a reservoir for volatile liquids.

In FIG. 2 - section of a device for supplying and discharging air - an annular duct (enlarged).

The respiratory system of the reservoir for volatile liquid, in particular, petroleum products, is designed to be installed on the reservoir 1, from the lower part of the body of which there are means for supplying and discharging volatile liquid, for example, petroleum products, equipped with a pump 2 for supplying oil and a pump 3 for collecting petroleum products connected to control unit 4.

On top of the tank 1 is a housing, for example, of a cylindrical shape, to the upper part of which a metal dome 5 is attached with a breathing valve 6. The valve type KDS2-1500 / 250, for example, can be used as a breathing valve. The number of breathing valves may be one, two or more, depending on the volume of the tank. In FIG. 1 shows, as an example, the respiratory system of a reservoir with two breathing valves 6.

The breathing valve 6 is designed to seal the gas space of the tank 1 with petroleum products and regulate the pressure in this space within specified limits. The rest of the respiratory system, designed to prepare the air before it is supplied to the breathing valve 6 and the removal of the gas mixture, is placed outside the tank.

The breathing valve 6 is connected with a system for supplying atmospheric air to the reservoir and for withdrawing from the reservoir air saturated with vapors of easily volatile liquid. The breathing valve 6 (each of the breathing valves 6) operates in two modes - as the inlet and the outlet when there is a change in pressure in the tank arising from whether the volatile liquid is pumped out from tank 1 or tank 1 is filling.

The system of supplying atmospheric air and venting from the reservoir of air saturated with vapors of easily volatile liquid is a single duct 7 of the supply and exhaust air located outside the reservoir 1 and connected to the breathing valve or to each of the breathing valves 6, if there are more than one valve (see Fig. . one).

The breathing valve 6, in communication with the internal volume of the tank 1, is placed inside the air supply / exhaust device, which is mounted on the dome 5 of the tank 1 and is made in the form of an annular (hollow) duct 8 (see Fig. 2), formed by two concentrically arranged shells 9 and 10, while the inner shell 9 is the inner wall of the annular cavity and at the same time limits the inner cavity of the annular duct 8 in which the breathing valve 6 is located, and the outer shell 10 is the outer wall of the annular floor awns. Above and below, the distance between the shells is closed by the bases 24, hermetically connected to the shells 9 and 10 with the formation of an annular cavity isolated from the surrounding atmosphere.

The breathing valve 6, located in the inner cavity of the annular duct 8, is installed with a gap relative to the inner shell 9, and the inner cavity of the annular duct is open to the surrounding atmosphere. The gap between the inner shell 9 of the annular duct 8 and the breathing valve 6 creates an air space between them, i.e. "Atmospheric clearance" 17, open to the surrounding atmosphere, for example, simultaneously from above and below.

On the inner surface of the annular duct, i.e. on the inner shell 9, slots 11 are made, communicating the annular cavity 12 with the inner cavity of the annular duct 8 bounded by the inner shell 9, and to the outer surface, i.e. to the outer shell 10, the air supply / exhaust duct 7 is connected, communicating the annular cavity of the annular duct 8 with air intake 13 through a dust filter 14 and a condenser-condenser 15 of air moisture (used when supplying atmospheric air to the tank 1) and with a refrigerator -condenser 16 vapors of volatile liquid (used when venting with vapors of volatile liquid from reservoir 1). The annular duct 8 has a gap relative to the surface of the dome of the tank 3, which provides unhindered removal of atmospheric precipitation from the working area along the conical slope of the roof 5.

The air inlet-outlet duct 7 is equipped with a feed pump 18, installed behind the atmospheric air intake means 13 in front of the condenser refrigerator 15 and connected to the control unit 4, including the feed pump 18 at the same time as the oil product (readily evaporating liquid) pump 3 from the reservoir 1. The duct 7, as described above, is connected to the device supply / exhaust air (ring duct 8). The air supplied to the breathing valve 6 through the annular duct 8, i.e. through the "atmospheric gap" 17 between the breathing valve 6 and the annular duct 8, previously dried due to the fact that the atmospheric air passing through the duct 7 from the means 13 (device) intake of atmospheric air to the breathing valve is passed through a refrigerator - condenser 15 atmospheric moisture located between the atmospheric air intake means 13 and the annular duct 8 surrounding the breathing valve 6. Condensate generated in the refrigerator-condenser 15 as a result of drying the atmospheric air is discharged into the tank 19 collecting atmospheric moisture. Thus, when pumping out an oil product, such as fuel, purified and dried air from an air preparation system, which includes an air purification unit from water and dust particles, a dust collector filter 14 and an air humidity refrigerator-condenser 15, due to the inclusion of pump 18 ( at the command of the control unit 4) enters the annular cavity 12 of the annular duct 8, then through the slots on the inner shell 9 of the annular duct 8, the drained air passes into its inner cavity, and then through the breathing valve 6 is sucked into the reservoir EXAMPLE 1 The system pumps the cleaned and dried air with an excess of 10%, to compensate for losses. Air consumption is determined by the readings of the flow meters of the fuel transfer pumps 2 of the oil product supply and 3 of the oil product intake, which give an exact figure of the fuel (oil product) consumption, and this figure is equal to the required air consumption (+ 10%), since the communicating volumes of air-fuel work.

When you turn on the pump 2, the supply of volatile liquid, in particular oil, for example fuel, into the tank 1, the air saturated with oil vapor is displaced through the breathing valve 6 into the cavity of the "atmospheric gap" 17 and through the slots 11 on the inner shell 9 of the annular duct 8 under the action pumping air pump 22 is sucked into the annular cavity 12, then this air is sent through the duct 7 to the refrigerator-condenser 16 of the vapor of easily volatile liquid. In the refrigerator-condenser 16, from the air saturated with vapor of an easily evaporating liquid, condensing liquid is removed by condensation, after which the condensate is drained into the tank 20 for condensing vapor of an easily evaporating liquid, and the air is discharged out through the tube 21. An exhaust air pump 22 is installed on the air duct in front of the refrigerator a condenser 16 vapors of a volatile liquid and is connected to a control unit 4, which includes a pump 22 simultaneously with the inclusion of a pump 2 for the supply of oil (volatile liquid) into reservoir 1.

The duct 7 is equipped with electric air dampers, which are installed in the duct 7 before and after the breathing valve. For example, an air AZD 214.000 air damper known in the art can be used. The electric drive of each damper 23 is connected to the control unit 4. Air dampers 23 are necessary to prevent the backflow of air when changing the operating mode of the supply and suction air pumps 18, 22. Each damper 23 opens while the other closes. The control unit 4 opens one of the shutters 23 simultaneously with the start of operation of the corresponding air pump - feed 18 or suction 22 (depending on whether the tank is empty or filled), which ensures the opening of the corresponding shutter and the passage of air flow along the branch of the duct 7, which is required engage in the process of emptying or filling the tank 1. The other damper is closed. In the rest state of the system (at a constant pressure inside the tank), both shutters 23 are closed to avoid unauthorized flow of air through the duct 7.

If a malfunction occurs in the air supply / pumping system or when the power supply of the claimed respiratory system is cut off, the breathing valve of the tank does not stop due to the presence of an “atmospheric gap” between the breathing valve and the annular duct connected with the surrounding atmosphere. In this case, unhindered access of ambient air to the breathing valve is provided, bypassing the system described above, i.e. in an emergency, the presence of an air supply / exhaust device (ring duct) allows for uninterrupted operation of the breathing valve without additional actions by personnel. When power is restored, the respiratory system automatically restores.

Claims (2)

1. The respiratory system of the reservoir for volatile liquid, containing at least one breathing valve, a system for supplying atmospheric air and exhaust from the reservoir of air saturated with vapor of volatile liquid, made in the form of a duct for supplying and discharging air connecting the breathing valve with an atmospheric intake air, a feed pump and a condenser condenser installed in front of the breathing valve, and connecting the breathing valve to the pump som and a fridge-condenser of vaporized liquid, while between the atmospheric air intake and the fridge-condenser of moisture in the duct a dust filter is installed, characterized in that the breathing valve in communication with the internal volume of the tank is also in communication with the atmosphere through the surrounding ring an air duct formed by two concentrically arranged shells between which there is an annular cavity isolated from the surrounding atmosphere, bounded by the indicated shells, while the breathing valve is installed in the inner shell formed by the inner cavity of the annular duct in communication with the surrounding atmosphere, the air valve being located at a distance from the inner shell, in addition, slots are made on the inner shell communicating the annular cavity of the annular duct with its inner cavity, and an air supply / exhaust duct is connected to the outer shell, communicating the annular cavity of the annular duct with the aforementioned atmospheric intake means air, a feed pump, a refrigerator-condenser of atmospheric moisture, a pump-down pump and a refrigerator-condenser of vapors of volatile liquid. 2. The respiratory system according to claim 1 or 2, characterized in that it is equipped with electric air dampers installed in the duct before and after the breathing valve, while the electric drive of each damper is connected to the control unit.

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