RU78440U1 - ENGINE FOR FUEL ADDITIVES - Google Patents

Abstract

The utility model relates to the field of technological processes and equipment for producing multicomponent mixtures of liquids, including those with solids, and can mainly be used to obtain liquid additives to motor fuels. The installation comprises at least two containers for liquid components, a container for producing a mixture, a pump system connected by pipelines to containers for liquid components and a container for producing a mixture, a nitrogen receiver configured to pulsed supply of nitrogen under pressure, and a tank for receiving the mixture is equipped with a bubbler collector mounted on its bottom and connected via a pipeline to a nitrogen receiver. The technical result consists in increasing the uniformity and chemical stability of the resulting mixture, as well as in increasing the fire-explosion safety of the operation of the installation. 1 n.p. 5 wp f-ly, 1 ill.

Description

The utility model relates to the field of technological processes and equipment for producing multicomponent mixtures of liquids, including those with solids, and can mainly be used to obtain liquid additives to motor fuels.

A known installation for producing high-octane gasolines (RU 4926 U1, 1997), which contains an expansion mixing tank, an additive tank, a cavitation hydrodynamic disperser-mixer in the form of a jet pump, in which the diffuser is in communication with an expansion mixing tank, and the suction pipe is in communication with a tank for additives, and a pump in which the inlet pipe is in communication with the expansion tank of the mixing, and the outlet pipe is in communication with the working nozzle of the cavitation hydrodynamic dispersant-mixer.

The disadvantage of this known installation is its limited functionality, since to produce high-octane gasolines it allows mixing only one liquid component with a powder additive.

A known installation for mixing liquid components in the production of winter diesel fuel (Danilov A.M. The use of additives in fuels for automobiles. - M .: Chemistry, 2000, p.193), which contains containers with liquid components, transfer and metering pumps and pipelines.

The specified known installation allows you to mix several liquid components, but provided for during its operation, mixing the liquid components during their flow in the pipeline does not provide a mixture of a homogeneous composition.

The closest in design and purpose to this utility model is the installation for multifunctional additives to motor fuel (RU 28051 U1, 2003). The specified installation contains containers for liquid components, a container for receiving a mixture, a pump system connected by pipelines with containers for liquid components and a tank for receiving a mixture, a container for mixing liquid and powder components with an input device for the powder component and a circulation circuit in the form of a pipeline and a transfer pump connected through a pumping system to one of the containers for the liquid component, a mixer connected by piping to the pumping system and a tank for Acquiring the mixture to form a circulation circuit due to the pipeline connecting the pumping system and the container to obtain a mixture, and a device for

vapor recovery, connected by drainage pipelines with tanks for liquid components and a tank to obtain a mixture.

In this known installation for a multifunctional additive to motor fuel, a dynamic mixer is used, which, when mixing a large number of liquid components in excess of, for example, five, does not ensure uniformity of the resulting mixture. The use in the known installation for producing a multifunctional additive to motor fuel of the provided pumping of a mixture of components along the circulation circuit allows to somewhat improve the homogeneity of the resulting mixture, but it takes a rather long time, amounting to several hours in practice.

Since the components of high-octane engine fuel additives and their mixtures are chemically unstable substances, which are subject to intense both homogeneous and heterogeneous oxidation by atmospheric oxygen, the oxygen contained in air tanks and pipelines leads to insufficient chemical stability of the resulting mixture and a high risk of fire or explosion during the process get multifunctional additives to motor fuel on a known installation, which is the closest analogue.

In the case of using powdered components, which are toxic substances, in the composition of the obtained additive, they sublimate and form explosive finely dispersed dust structures, the danger of an explosion or fire increases even more when a seemingly quite simple technological operation of loading a powdered component into a container is performed.

Therefore, the disadvantages of the known installation for producing multifunctional additives to motor fuel, which is the closest analogue, are the lack of uniformity and chemical stability of the resulting mixture, as well as the high risk of explosion or fire during its operation.

The objectives of this utility model are to increase the uniformity and chemical stability of the resulting mixture, as well as to increase the fire-explosion safety of the operation of the installation.

The tasks are solved, according to this utility model, in that an installation for producing an additive to motor fuel, containing, in accordance with the closest analogue, at least two containers for liquid components, a container for producing a mixture and a pump system connected by pipelines to containers for liquid components and capacity to obtain

mixture, differs from the closest analogue in that it is equipped with a nitrogen receiver configured to pulsed supply of nitrogen under pressure, and the tank for receiving the mixture is equipped with a bubbler collector installed at its bottom and connected via a pipeline to the nitrogen receiver.

Moreover, the installation for producing an additive to motor fuel is equipped with a container for mixing liquid and powder components, connected by pipelines through the pumping system to one of the containers for the liquid component, and a container for mixing liquid and powder components is provided with a circulation loop formed by the pipeline and the transfer pump, and a vacuum receiver mounted above the level of the liquid component with the possibility of suction of suspended particles of the powder component in air at downloading it.

The installation for producing an additive to motor fuel is also equipped with drainage pipes connected to containers for liquid components and a container for receiving the mixture, a breathing valve connected to drainage pipes and a nitrogen receiver, and a vapor recovery device made in the form of an absorber, connected to a pipe with a breathing valve and communicating with the atmosphere. The nitrogen receiver is piped to the pump system.

Providing a unit for producing an additive to motor fuel with a nitrogen receiver configured to provide pulsed nitrogen supply under pressure, as well as supplying a container for receiving the mixture with a bubbler collector installed at its bottom and connected via a pipeline to a nitrogen receiver, provides the possibility of a pulsed nitrogen supply under pressure in the container to obtain the mixture under the mixture layer, as a result of which, firstly, sufficiently intensive mixing of the components of the mixture is provided and increases about heterogeneity resulting mixture. Secondly, pulsed sparging with nitrogen under pressure leads to the removal of air oxygen from the tank to obtain the mixture and from the resulting mixture itself, which increases the chemical stability of the resulting mixture and increases the fire-explosion safety of the operation of the installation.

Providing a container for mixing liquid and powder components of an installation for producing an additive to motor fuel (if used to obtain an additive containing a powder component) with a vacuum receiver installed above the level of the liquid component with the possibility of sucking in the air suspended particles of the powder component during loading prevents explosive formation

fine dust structures of the powder component and also leads to increased fire and explosion safety of the operation of the installation.

The supply of the installation for receiving an additive to motor fuel with a nitrogen receiver, configured to pulsed supply of nitrogen under pressure and connected by a pipe to the pump system, allows nitrogen to purge the internal cavities of all elements of the installation, providing air removal and increasing fire and explosion safety.

The aforementioned testifies to the solution of the stated tasks of the present utility model due to the presence of the above distinguishing features of the installation for producing additives to motor fuel.

The drawing shows a structural diagram of a plant for producing additives to motor fuel, where 1 ₁ -1 _N is a tank for a liquid component, 2 is a tank for mixing liquid and powder components, 3 is a tank for producing a mixture, 4 is a pump system, 5 is nitrogen receiver, 6 - transfer pump, 7 - bubbler collector, 8 - breathing valve, 9 - vapor recovery device, 10 - atmospheric line valve and 11 - nitrogen line valve.

A plant for producing an additive to motor fuel contains at least two containers 1 ₁ -1 _N for a liquid component, a container 3 for producing a mixture, a container 2 for mixing liquid and powder components and a pumping system 4 connected by pipelines to containers 1 ₁ - 1 _N for a liquid component, with a capacity of 3 to obtain a mixture and a capacity of 2 for mixing liquid and powder components. The installation also contains a breathing valve 8, equipped with a valve 10 of the atmospheric line and a valve 11 of the nitrogen line and connected by drainage pipes with capacities 1 ₁ -1 _N for the liquid component and capacity 3 for receiving the mixture, a nitrogen receiver 5 configured to pulsed supply of nitrogen under pressure and connected by pipelines to the pump system 4 and the breathing valve 8, and the device 9 for trapping vapors in the form of an absorber, which is made in the form of a column filled with water, connected by a pipeline to the respiratory valve to 8 and communicates with the atmosphere. The container 2 for mixing liquid and powder components is equipped with a transfer pump 6, which is connected to it by pipelines with the formation of a circulation circuit, as well as a vacuum receiver (not shown in the drawing) installed above the level of the liquid component with the possibility of suction of particles of the powder component suspended in air when it loading into a container 2 for mixing liquid and powder components. In addition, a vacuum receiver (on

not shown) is configured to deposit particles of the powdered component contained in the air stream it sucks on the surface of one of the liquid components contained therein. The tank 3 for receiving the mixture is equipped with a bubbler collector 7, which is installed on its bottom and connected via a pipeline to a nitrogen receiver 5.

Installation for receiving additives to motor fuel works as follows.

Before starting the process of filling the installation with the components of the resulting mixture, the installation operator, using a valve (not shown) supplies nitrogen under pressure from the nitrogen receiver 5 to the pump system 4, through which nitrogen is distributed through pipelines to remove all atmospheric air from the internal cavities. Using a pumping system 4, each liquid component is pumped through a pipeline into its own container 1 ₁ -1 _N for the liquid component. If a powder component is used as part of the additive obtained, a predetermined amount of one of the liquid components is piped through the pumping system 4 to a container 2 for mixing the liquid and powder components, where then the required amount of the powder component is loaded. Particles of a powdered component suspended in air that form above the surface of a liquid component when it is loaded into a container 2 for mixing liquid and powder components are sucked in by a vacuum receiver (not shown in the drawing) and deposited on the surface of the liquid component contained in it. The transfer pump 6 performs the pumping of the mixture of the liquid component and the powder component along the circulation circuit, providing a homogeneous mixture.

The resulting mixture of liquid and powder components from a container 2 for mixing liquid and powder components is pumped through pipelines through a pumping system 4 into a tank 3 to obtain a mixture into which specified quantities are supplied through pipelines from containers 1 ₁ -1 _N for a liquid component through a pumping system 4 other liquid components. Next, the installation operator, using a valve (not shown), supplies nitrogen under pressure from the nitrogen receiver 5 to the bubbler collector 7. The nitrogen exiting the bubbler collector 7 intensively mixes the mixture of components in the tank 3 to obtain the mixture and remove air from it and the oxygen contained therein, providing a uniform and chemically stable mixture.

When the pressure in tanks 1 ₁ -1 _{N is} exceeded for a liquid component or in tank 3, valve 10 opens to obtain a preset mixture

atmospheric line and the valve 12 of the nitrogen line of the breathing valve 8 closes, as a result of which the indicated containers communicate with the atmosphere through the drainage pipes, the breathing valve 8, and the vapor recovery device 9, thereby reducing the overpressure in them. In this case, the pairs of components and the resulting mixture are captured by the vapor recovery device 9, which prevents environmentally hazardous emissions into the atmosphere. If the pressure decreases in the containers 1 ₁ -1 _N for the liquid component or in the tank 3 to obtain a mixture to a level lower than the specified value, the atmospheric line valve 10 closes and the nitrogen valve of the breathing valve 8 opens and into the indicated containers from the nitrogen receiver 5 through the breathing valve 8 through the drainage piping nitrogen enters, preventing the ingress of moisture and atmospheric air.

If necessary, adjust the percentage of components in the composition of the finished mixture, the required amount of a component from the corresponding tank 1 ₁ -1 _N for the liquid component through pipelines through the pumping system enters the tank 3 to obtain the mixture, after which the mixture is again pulsed by bubbling nitrogen bubbling manifold 7 from the nitrogen receiver 5.

The resulting additive to motor fuel from the tank 3 to receive the mixture through pipelines through the pumping system 4 is shipped to the consumer.

The discharge of residual liquid components and the resulting additives from the cavities of all elements of the installation provides a nitrogen receiver 5.

The applicant has created a prototype installation for producing an additive to motor fuel, which is the subject of this utility model, and tested it for the purpose of producing an additive to engine fuel based on aliphatic alcohols C ₁ -C ₅ , ethers, aromatic amines and high octane hydrocarbons. The prototype installation showed the possibility of obtaining additives to motor fuel, characterized by a sufficiently high chemical stability and homogeneity of the resulting mixture. The introduction of such an additive in gasoline increases its octane number, increases thermo-oxidative stability and anticorrosion properties, and also reduces the content of harmful substances in the exhaust gases of an internal combustion engine.

Thus, the present utility model provides an increase in the uniformity and chemical stability of the resulting mixture, as well as an increase in the fire-explosion safety of the operation of the installation.

Claims (6)

1. Installation for producing additives to motor fuels, containing at least two containers for liquid components, a container for receiving a mixture and a pump system connected by pipelines to containers for liquid components and a tank for receiving a mixture, characterized in that it is equipped with nitrogen a receiver configured to pulsed supply of nitrogen under pressure, and the tank for receiving the mixture is equipped with a bubbler collector mounted on its bottom and connected via a pipeline to a nitrogen receiver. 2. Installation according to claim 1, characterized in that it is equipped with a container for mixing liquid and powder components, connected by pipelines through the pumping system to one of the containers for the liquid component. 3. Installation according to claim 1 or 2, characterized in that its capacity for mixing liquid and powder components is provided with a circulation circuit formed by the pipeline and a transfer pump. 4. Installation according to claim 1 or 2, characterized in that its capacity for mixing liquid and powder components is equipped with a vacuum receiver mounted above the level of the liquid component with the possibility of suction of airborne particles of the powder component when it is loaded. 5. Installation according to claim 1, characterized in that it is equipped with drainage pipes connected to containers for liquid components and a container for receiving the mixture, a breathing valve connected to drainage pipes and a nitrogen receiver, and a vapor recovery device made in the form of an absorber, connected by a pipe to the breathing valve and communicating with the atmosphere. 6. Installation according to claim 1, characterized in that the nitrogen receiver is connected by a pipeline to the pumping system.