RU2041861C1 - Method of processing oil slime and trap oils - Google Patents

Abstract

FIELD: coal chemistry. SUBSTANCE: oil slimes and trap oils were subjected for settling at 60-100 C. Sediment is subjected for oxidative cracking by spraying latter in the closed volume with a mixture of air and steam heated up to 400-500 C for 0.5-6.0 s, cooled, and liquid phase is separated. Oxidative cracking is carried out at the mass ratio sediment air steam 1: (0.2-0.3): (0.05-0.15). Before cracking sediment can be mixed with water-soluble metal salts of transient valency, such as iron, chrome, nickel, cobalt, tungsten taken at concentration 0.02-0.5 wt.-% (as salt). EFFECT: improved method of oil processing. 4 cl, 1 dwg, 1 tbl

Description

 The invention relates to the oil and oil refining industry and can be used in the processing of oil sludge and trap oils for marketable oil and raw materials for the production of asphalt.

A known method of processing oil sludge and trap oils by centrifugation [1]
The disadvantage of this method is the high energy costs, as well as the intensive wear of moving mechanisms due to the abrasive effects of fur impurities in the feed.

The closest to the invention in technical essence and the achieved result is a method of processing oil sludge by sludge, mixing with a solvent and subsequent sedimentation of solid residues [2]
The known method is not effective enough, differs in the duration of the process, insufficient depth of separation of mechanical impurities, relatively high yield of solvent, low yield of the finished product, i.e. commercial oil.

 The aim of the invention is to increase the efficiency of the method.

The goal is achieved in that in the process of processing oil sludge trap and oils, comprising the sludge and the separation of solids and water, the sludge is carried out at a temperature of 60-100 ^{° C} and further separated oil or slurry oil pot is sprayed in a closed volume to a temperature of the heated 400- 500 ^about With a mixture of air and water vapor, conduct oxidative cracking for 0.5-6 s, cool and isolate the liquid phase. The ratio between oil sludge or trap oil, air and water vapor is respectively 1: (0.2-0.3) :( 0.05-0.15). Before spraying, oil sludge or trap oil can be mixed with water-soluble salts of metals of variable valency in an amount of 0.02-0.5% by weight per active metal. Water-soluble salts of iron, chromium, nickel, cobalt, tungsten are used as metal salts of variable valency.

Raw materials for the implemented technology are:
1. Trap oil, which is sludge from the reservoirs of the technological chain of oil preparation, consists of heavy petroleum hydrocarbons (mainly resinous and asphaltene) in the form of extremely persistent water-oil emulsions containing fine particulate matter and water up to about 20 wt. For example, the trapped oil from the oil-gathering station Otradny is a collection of Bashkir and Tatar oil with the following characteristics: Kinematic viscosity at 50 ° ^C of 12 cSt; density at 20 C ^of 898 kg / m ^3; pour point 21 ^о С. The beginning of oil boiling is 65 ^о С, 10% is distilled at 105 ^о С, 51% distillate is distilled off to a temperature of 480 ^о С. Content of mechanical impurities 2.6% Granulometric composition of impurities: more than 1 mm 5% 0.5-1.0 mm 19% 0.3-0.5 mm 22% 0.01-0.3 54%
2. Oil sludge, which is an emulsion of the type "water-oil" of heavy oil and petroleum products, dumped in dumps, barns, pits or accumulated in tanks, contains from 1 to 50 wt. mechanical impurities and, accordingly, the same amount of water. The most common content of impurities and water is from 2 to 15 wt. For example, oil sludge from petrochemical complex barn Perm Perm is a mixture of heavy hydrocarbons discharged from refinery and petrochemical plants, accumulated for many years in open barns, and has the following characteristics: Kinematic viscosity at 50 ^C is 9 cSt, density at 20 ^about 965 kg / m ³ ; pour point 23 ^{° C;} initial boiling point 72 ^{° C,} 10% distilled at 112 ^C to a temperature 480 ^{° C} 48% distilled distillate. The content of water and mechanical impurities in the sludge is 15%. Granulometric composition of impurities, wt. more than 1 mm 15; 0.5-1.0 mm 22; 0.3-0.5 mm 31; 0.01-0.3 mm 32.

 To implement the method of processing oil sludge and trap oils, a technological scheme and a processing plant have been developed.

The technological scheme includes the following main operations:
preliminary heating and collection of oil sludge or trap oil;
separation from the main quantity of mechanical impurities and their evacuation;
oxidative or oxidation-catalytic conversion of the liquid part of the separated oil sludge or trap oil;
quenching of reaction products (cooling);
separation of commercial oil from gas, water and residual impurities.

 In accordance with the technological scheme, an installation for the processing of oil sludge and trap oils was assembled, shown in the drawing.

 The installation includes a barn 1 for storing raw materials, which is oil sludge or trap oil, connected by a pipeline 2 of raw materials with a pump 3, a heat exchanger 4 and a separator 5 of raw materials. The raw material separator 5 is connected by a sludge pipe 6 to a sump 7, a separated liquid phase pipe 8 with a pump 9 and nozzles 10 of a dual reactor 11, and is also equipped with a gas discharge pipe 12. An air pipe 13 is connected to the nozzles 10, connected to a compressor 14, a heat exchanger 15, an electric furnace 16, and a gas supply pipe 17. The reactor 11 is connected by a gas pipe 18 to a steam generator 19, a heat exchanger 15 and a commercial oil separator 20. The commodity oil separator is connected by a pipe 21 to a sump-separator 22, a pipe 23 with a gas discharge pipe 12, and is also equipped with a pipe 24 for the removal of commercial oil. The water supply 25 is connected to a pump 26, a steam generator 19, a pump 4 and a heat exchanger 27 for heating the sludge.

 Installation works as follows.

Oil sludge or trap oil in the barn 1 is heated using a heat exchanger 27. Steam is supplied to the heat exchanger 27 from the steam generator 19, while part of the heat of the steam is lost in the heat exchanger 4. Hot steam to heat the oil sludge or trap oil can be supplied from the steam generator 19 or the factory network . Heated oil or slurry oil pot 2 through line 3 raw material is pumped through the heat exchanger 4, wherein the feedstock is further heated to a temperature of 60-100 ^{° C} and further to a separator 5 feedstock. In the separator 5, the main part of the mechanical impurities is separated up to 95-97%, the main part of the water is separated up to 70-80%, the gas and the oil liquid phase are separated. The separation rate of solids is 8-15 cm / h. The separated mechanical impurities and water are passed through the sludge pipe 6 to the sump 7. The gas is sent to the discharge pipe 12. The separated oil liquid phase is pumped through the separated liquid phase 8 pipe to the nozzles 10 of the dual reactor 11. Into the same nozzles 10 is the compressor 14 through the air pipe 13 pump air, which is heated in the heat exchanger 15 and the electric furnace 16. Before the electric furnace 16, steam is pumped into the air pipe from the pipe 17.

The ratio between oil sludge or trap oil, air and water vapor is respectively 1: (0.2-0.3) :( 0.05-0.15) wt. Water vapor is considered the total of the remaining water in the oil sludge (trap oil) and the injected steam. In the reactor 11, the liquid phase is sprayed heated to a temperature of 400-500 ^about With air and water vapor. Under the influence of temperature, air and water vapor, the liquid oil phase undergoes oxidative cracking. Part of the oil is oxidized, increasing the temperature to 450-650 ^about C. The duration of oxidative cracking is 0.5-6 s. In this case, the pressure in the reactor 11 may increase to 10 atm.

 The reaction products in gaseous form go to quenching (cooling) through gas pipelines 18 to heat exchangers 19 and 15. The heat exchanger 19 performs the function of a steam generator, since in it the reaction products are cooled by water pumped by pump 26. Part of the resulting steam is sent to the air supply line to the electric furnace 16, and part for heating the raw materials in the barn 1 and the heat exchanger 4. After the final cooling in the heat exchanger 15, the reaction products in the gas and liquid phase are fed to the commercial oil separator 20, where the final separation into gas takes place, directed by pipeline 23 into the gas discharge line 12, for commercial oil sent to the commercial oil drain pipe 24, and to mechanical impurities and water sent through the pipe 21 to the separator 22. Gas from the gas discharge pipe 12 is spent on technological needs, and mechanical impurities are used in the manufacture of road surfaces. Before feeding the separated liquid phase into reactor 11, it is possible to mix with water-soluble salts of metals of variable valency: iron, chromium, nickel, cobalt, tungsten, etc. Metal salts of variable valence initiate oxidative-catalytic conversions of the separated liquid phase, contribute to a deeper conversion of the liquid phase into a commodity oil. The amount of metal salts of variable valency is from 0.02 to 0.5 wt. on the active metal from the liquid phase.

EXAMPLE EXAMPLE 1. Novootradnenskogo trapped oil from the oil collecting point in an amount of 100 kg settled for 10 hours at a temperature of 60 ^C. The rate of the sludge was 8 cm / hr, the release of water to 80% solids 95% water separation and mechanical impurities. The separated liquid phase is fed to a reactor where the pulverized heated to 400 ^{° C} a mixture of air and steam in the ratio of 1: 0.2: 0.05 by weight. The mixture is kept in the reactor for 6 s, cooled and the liquid phase, which is a commercial oil, is separated.

PRI me R 2. Perform as example 1. As a raw material used oil sludge Perm petrochemical complex. The temperature of the sludge administered 80 ^C, standing time 9 h Spray liquid phase is heated to a temperature of 450 ^{° C} a mixture of air and steam in the ratio of 1:. Of 0.25: 0.10 by weight. The mixture is kept in the reactor for 3 s, cooled and the crude oil is separated.

EXAMPLE EXAMPLE 3. Carry out as in Example 1, the sludge temperature is prescribed 100 ^{° C,} 8 hours standing time Spray the liquid phase is heated to a temperature of 500 ^{° C} a mixture of air and steam in the ratio of 1:. 0.3: 0 15 by weight. The mixture is kept in the reactor for 0.5 s, cooled and the crude oil is separated.

 PRI me R 4. Perform as example 1, but before spraying the trap oil is mixed with cobalt naphthenate in an amount of 0.02 wt. calculated on cobalt.

 PRI me R 5. Perform as example 2, but before spraying the trap oil is mixed with chromium trioxide in an amount of 0.25 wt. calculated on chrome.

 PRI me R 6. Perform as example 3, but before spraying the trap oil is mixed with iron sulfate in an amount of 0.5 wt. based on iron.

 The properties of the crude oil obtained in examples 1-6 are presented in the table.

 From the table it follows that the oil obtained by the proposed method has less water, impurities, has a lower density.

Claims (4)

1. METHOD FOR PROCESSING OIL SLUDGES AND TRAP OILS, including the separation of solids and water from them by the sludge method, characterized in that the sludge is carried out at 60-100 ^° C, the settled oil sludge and trap oil are additionally subjected to oxidative cracking by spraying the latter in a closed volume to a heated temperature 400 500 ^o With a mixture of air and water vapor for 0.5 to 6.0 s, cool and separate the liquid phase.  2. The method according to claim 1, characterized in that the oxidative cracking is carried out at a ratio of settled oil sludge or trap oil air water vapor equal to 1 (0.2 0.3) (0.05 0.15).  3. The method according to claim 1, characterized in that prior to oxidative cracking, separated oil sludge and trap oil are pre-mixed with water-soluble metal salts of variable valency in an amount of 0.02 to 0.5 wt. on the salt.  4. The method according to claim 3, characterized in that water-soluble salts of iron, chromium, nickel, cobalt, tungsten are used as metal salts of variable valency.

Images