RU50219U1 - REACTOR FOR THE PROCESSING OF HYDROCARBON RAW MATERIALS - Google Patents

Abstract

The utility model is based on the comprehensive task of increasing the overhaul period and improving the quality of the resulting product. The hydrocarbon processing reactor includes a gas mixture ignition unit and a prefabricated cooled case including a working body formation chamber, a pyrolysis chamber with a feedstock for processing the processed raw materials, and a quenching chamber. Pipes for supplying and removing reagents are connected to the housing. The reactor differs from the prototype in that it additionally contains a hot gas generator, the output of which is connected to the input of the chamber of formation of the working fluid. The hot gas generator has an internal combustion chamber, the walls of which are coaxial to the body of the hot gas generator. The inlet end of the hot gas generator is designed to connect to the oxidizer gas supply line. The combustion chamber communicates with the ignition unit of the gas mixture and is equipped with a supply pipe for initiating combustion of gas. A collector with radial holes is installed in the input part of the chamber for the formation of a working fluid. The manifold communicates with the fuel supply pipe. Between the chamber of formation of the working fluid and the pyrolysis chamber is located the feed unit of the processed raw material, made in the form of radial nozzles mounted on the reactor vessel. Between the pyrolysis chamber and the quenching chamber, a hydrogen or hydrogen-containing gas supply unit is arranged in the form of radial nozzles mounted on the reactor vessel. In the quenching chamber, catalytic elements can additionally be installed, which are preferably made in the form of transversely mounted grids coated with a catalyst.

Description

The utility model relates to the field of hydrocarbon processing, namely, devices for processing including bottoms, tar, bitumen, fuel oil, etc.

A known reactor for processing secondary heavy hydrocarbon feeds [RF Patent 2170754, MKI C 10 G 7/00, published July 20, 2001]. The reactor has a housing in which perforated partitions are placed oriented perpendicular to its axis. The reactor is also equipped with a unit for supplying a heavy hydrocarbon feedstock, a unit for supplying an activating agent, for example, a propane-butane-hydrogen mixture, an unit for introducing recycled processing residues, and an unit for withdrawing the vapor-gas mixture. When the raw material and the activating agent move through the perforation holes, the mass flow disperses with the formation of bubbles and due to this, the contact surface of the raw material and the activating agent increases. In the process of moving this dispersed stream from the first baffle to the last, not only the distillation of light fractions contained in the feedstock is intensified, but also the chemical interaction of the processed feed with the activating gas and the pairs of newly formed light fractions of hydrocarbons is intensified and the process of conversion of heavy hydrocarbons to bright. During convector operation, the process temperature in the reaction zone reaches ≈ 300 ° С. The yield of light products, although higher than in the known processes of delayed coking and vacuum distillation, however, is about 53% of the _mass.

Known hydrodynamic cavitation reactor [RF Patent 2124550, MKI C 10 G 15/08, publ. 10.01.99], in a hermetically sealed housing, made in the form of a vertically oriented cylindrical glass, with the help of dividing walls formed working chambers. Hydrocarbon feedstock, together with water, is supplied to the reactor under high pressure (180-220 atm) and enters the perforated swirl. Then, the turbulized dispersed vapor-liquid flow through the nozzles of the nozzle installed at the outlet of the swirler enters sequentially into the working chambers. The working chambers communicate with each other through nozzles. In the working chambers in the area of high pressure, the steam bubbles collapse and a resonant cavitation process occurs, which causes the generation of acoustic radiation acting on the raw material. This leads to the destruction of molecules of heavy hydrocarbon feeds, which ensures a high percentage of the yield of light fractions.

The above analogs allow the processing of heavy hydrocarbons into light fractions due to cavitation physicochemical processes leading to the destruction of molecules.

The closest to a utility model for the combination of essential features is a reactor for the processing of hydrocarbons [RF Patent No. 2206387, publ. 20.06.2003]. In the prefabricated water-cooled reactor vessel there is a pyrolysis chamber and a quenching chamber made in the form of an expanding nozzle into which water enters from the reactor water cooling system. In the pyrolysis chamber, a hydrocarbon feed assembly is arranged in the form of longitudinally oriented perforated tubes. Working body education

carried out using a burner in which a mixture of combustible gas and an oxidizing agent is burned. The combustion of the gas mixture is initiated using the ignition unit. The prototype has several disadvantages. Firstly, the coking phenomenon, since the holes of the longitudinally oriented tubes become clogged, which leads to the cessation of the feed. This necessitates a shutdown of the reactor for maintenance and repair work. Secondly, there is no uniform distribution of reagents over the cross section of the pyrolysis chamber, which makes the processing depth insufficient. Thirdly, an emulsified mixture of pyrolysis products is created in the quenching chamber, which also reduces the quality of the resulting product.

The utility model is based on the comprehensive task of increasing the overhaul period and improving the quality of the resulting product.

The problem is solved by changing the design.

The reactor for processing hydrocarbon feedstocks includes a gas mixture ignition unit and a prefabricated cooled case including a working body formation chamber, a pyrolysis chamber with a feedstock of the processed raw material and a quenching chamber. Pipes for supplying and removing reagents are connected to the housing. The reactor differs from the prototype in that it additionally contains a hot gas generator, the output of which is connected to the input of the chamber of formation of the working fluid. The hot gas generator has an internal combustion chamber, the walls of which are coaxial to the body of the hot gas generator. The inlet end of the hot gas generator is designed to connect to the oxidizer gas supply line. The combustion chamber communicates with the ignition unit of the gas mixture and is equipped with a supply pipe for initiating combustion of gas. In the input part of the camera

collector with radial holes is installed working body formation.

The manifold communicates with the fuel supply pipe. Between the chamber of formation of the working fluid and the pyrolysis chamber is located the feed unit of the processed raw material, made in the form of radial nozzles mounted on the reactor vessel. Between the pyrolysis chamber and the quenching chamber, a hydrogen or hydrogen-containing gas supply unit is arranged in the form of radial nozzles mounted on the reactor vessel.

In the quenching chamber, catalytic elements can additionally be installed, which are preferably made in the form of transversely mounted catalyst coated grids.

The essence of the utility model is illustrated by the Figure, which shows a longitudinal section of the reactor.

The reactor has a cylindrical horizontally oriented housing with an outer wall 1 and an inner wall 2. Between the walls there is an annular gap into which refrigerant, for example, water, air, nitrogen, etc., is supplied and discharged by pipes 3.

The main components of the reactor are a hot gas generator 4, a chamber 5 for forming a working fluid, a pyrolysis chamber 6, a quenching chamber 7, and a gas mixture ignition unit 8. Inside the casing of the hot gas generator 4, a combustion chamber 9 is made, the walls 10 of which are coaxial to the walls of the casing of the hot gas generator 4 and there is an annular slot gap between them 11. The combustion chamber 9 is connected to the gas mixture ignition unit 8 by means of a pipe 12. The combustion chamber 9 is also provided with a nozzle 13 for supplying a gas initiating combustion (for example, propane-butane, methane, propane, hydrogen

etc.). The inlet end of the housing of the hot gas generator 4 has a flange 14, with an axial hole 15, designed to introduce gas - an oxidizing agent (oxygen, air). The output part of the housing of the hot gas generator 4 (and, consequently, the walls 10 of the combustion chamber 9) is conically narrowed and connected to the body of the chamber 5 forming the working fluid conically expanding at the inlet. At the beginning of the cylindrical part of the chamber 5, a collector is installed, which is a sleeve 16 with radial holes 17. Between the sleeve 16 and the body of the chamber 5 of the formation of the working fluid there is an annular slotted gap communicating with the fuel supply pipe 18.

The feed node of the processed raw materials is located between the chamber 5 of the formation of the working fluid and the chamber 6 of the pyrolysis. It is made in the form of a spacer 19 with radial nozzles 20, evenly distributed over the ring. The hydrogen supply unit is located between the pyrolysis chamber 6 and the quenching chamber 7. It is also made in the form of spacers 21 with radial nozzles 22. Catalytic elements 23 can be located in the quenching chamber 7. They are a series of transversely mounted lattices coated with a catalyst. The quenching chamber is equipped with water supply pipes 24.

The cases of the generator 4, chambers 5, 6, 7 have the same diameter, and form a prefabricated reactor vessel.

A unit 8 for igniting the gas mixture is fixed on the reactor vessel. It is equipped with a pipe 25 for supplying a combustion initiating reagent and a pipe 26 for supplying an oxidizing agent and an ignition device (not shown in the Figure).

The reactor operates as follows.

First, an oxidizing agent is supplied through the opening 15, for example, air, which passes through the gap 11 and simultaneously enters the combustion chamber 9. Then through the pipe 13 in the combustion chamber 9 is fed a gas that initiates combustion, for example, propane-butane. An oxidizing agent, for example, air and a gas initiating combustion, for example, butane propane, is supplied to the ignition unit 8 of the ignition of the gas mixture, respectively, through the nozzles 25 and 26, the mixture is ignited, and accordingly, the reaction begins in the combustion chamber. At the outlet of the combustion chamber 9 (in the conical part of the housing), hot gases are mixed with air leaving the slot gap 11, which leads to turbulence in the flow. When entering the operating mode in the combustion chamber 9, the temperature is 740-1000 ° C with an oxygen excess coefficient α = 1.5.

In the chamber 5 of the formation of the working fluid through the holes 17 in the sleeve 16 is supplied fuel by jets perpendicular to the direction of the main stream. In this chamber, the afterburning of the gas mixture and the formation of a working fluid take place. Upon reaching the operating mode in chamber 5, the temperature is 1200-1600 ° C at α = 0.95-1.0.

The injection of the processed raw materials is carried out by radial flows through the nozzles 20. The processed raw materials, driven by the flow of the working fluid, enters the pyrolysis chamber 6. High-speed heating occurs here, accompanied by the destruction of high molecular weight components. Flow turbulence and cavitation processes increase the degree of destruction of macromolecular compounds. When entering the operating mode in the chamber 6 of the pyrolysis temperature is 500-800 ° C.

In order to exclude the presence of unsaturated hydrocarbons (ethylene, butylene, propylene, etc.) in the finished product at the outlet of the pyrolysis chamber 6

hydrogen or hydrogen-containing gases, such as ammonia, are injected.

The supply of hydrogen or hydrogen-containing gases is also carried out through radially mounted nozzles 22.

The products of pyrolysis, additionally subjected to a turbulizing effect of hydrogen, enter the quenching chamber 7. The water coming from the nozzles 24 turns into steam, the temperature of the vapor-gas mixture decreases to 300-450 ° C and the pyrolysis process stops. Condensed hydrocarbons are at least 90% composed of light fractions.

Separation into fractions of the mixture obtained at the outlet is carried out in the traditional way.

During the operation of the reactor, all parts of its body are cooled by passing refrigerant, for example, water in the gap between walls 1, 2. The design of the reactor allows the processing of heavy hydrocarbons with different physicochemical characteristics.

The operation of the reactor is tested on various feedstocks. The following are test examples.

Example 1. The inventive reactor was used to process the bottom residue of the gas condensate plant of the Surgut ZSK, the density of the raw materials at 20 ° C was 870.9 kg / m ³ . During the operation of the reactor, no activating gas or modifying agent was supplied to the reactor. As a result, the following products were obtained,% of the masses: 12 — light hydrocarbons (C ₁ -C ₄ ), 4 — light hydrocarbons (C ₅ -C ₆ ), 82.5 — reaction mixture to obtain light hydrocarbon fractions at a refinery, 1, 5- - solid particles and losses.

Example 2. The same feedstock as in Example 1 was processed in a reactor under conditions of hydrogen supply to the reactor. As a result, the following products were obtained, wt%: 2.3 — light hydrocarbons (C ₁ -C ₆ ), 95.7 — reaction mixture to obtain light hydrocarbon fractions at a refinery, 2 — solid particles and losses.

Example 3. The reactor was used for the processing of natural petroleum bitumen, density at 20 ° C, - 930 kg / m ³ . During the operation of the reactor, hydrogen was supplied to the reactor. As a result, the following products were obtained, wt%: 11.2 - light hydrocarbons (synthesis gas), 83.8 - reaction mixture for producing light hydrocarbon fractions at a refinery, 5 - solid particles and losses.

Example 4. In the reactor, fuel oil M-100 was processed, viscosity at 20 ° C - 16 mm / s, also when hydrogen was supplied. As a result, the following products were obtained, wt%: 17 — light hydrocarbons (C ₁ -C ₆ ), 76 — reaction mixture to obtain light hydrocarbon fractions at a refinery, 6 — solid particles and losses.

The above and other numerous tests of the reactor showed that it allows the processing of heavy hydrocarbons with a yield of light hydrocarbon fractions of 90-98%. The specific percentage is determined by the physico-chemical characteristics of the processed raw materials and the amount of hydrogen supplied to the reactor.

Tests have shown that, compared with the prototype, the percentage of particulate matter and loss is reduced by an average of 30%.

The claimed design eliminates the possibility of coking, because raw materials are fed through radial nozzles, which significantly increases the overhaul period.

The high dispersion of the jets entering the reagent pyrolysis chamber reduces the time of high-speed heating and increases the productivity of the reactor. The organization of turbulent flows increases the degree of destruction and, consequently, the yield of the reaction mixture to obtain light fractions of hydrocarbons.

The presence of catalysts in the quenching chamber improves the quality of the resulting finished product (gasoline, diesel fuel), namely, the percentage of olefin-containing hydrocarbons decreases and increases the octane number.

The reactor can use associated gases, methane, butane, etc., as fuel, including the use of gases from the operation of the reactor. The heat released during operation can be used to preheat the processed raw materials, or otherwise be disposed of.

Claims (3)

1. A reactor for processing hydrocarbon feedstocks having a gas mixture ignition unit and a collection case including a working body formation chamber, a pyrolysis chamber with a feedstock processing unit, a quenching chamber, nozzles for supplying and discharging reagents are connected to the body, characterized in that it further comprises a hot gas generator, the output of which is connected to the input of the working fluid chamber, the hot gas generator has an internal combustion chamber, the walls of which are coaxial to the body of the hot gas generator, the combustion chamber communicates with the ignition unit of the gas mixture and is equipped with a nozzle for supplying a gas initiating combustion, while a manifold with radial holes is installed in the input part of the chamber for forming a working fluid, the collector communicates with a nozzle for supplying fuel, and a feed unit for processing raw materials, made in the form of radial nozzles mounted on the reactor vessel, between the pyrolysis chamber and the quenching chamber is a hydrogen or hydrogen supply unit containing gas, designed as a radial nozzles mounted on the reactor vessel. 2. The reactor according to claim 1, characterized in that the catalytic elements are additionally installed in the quenching chamber. 3. The reactor according to claim 2, characterized in that the catalytic elements are transversely mounted lattices coated with a catalyst.