RU61151U1 - INSTALLATION OF FRACTIONATION OF HYDROCARBON RAW MATERIALS - Google Patents

Abstract

The utility model relates to the petrochemical industry. The installation contains a raw material supply line, several stages of distillation and a line for removing liquid fractions, each stage of distillation includes a furnace heat exchanger connected in series by pipelines, an evaporator and a condenser, to which a liquid fraction removal line is connected, including a refrigerator connected in series, and a storage tank pump, tank and outlet pump; a raw material supply line is connected to the heat exchanger of the furnace of the first stage of acceleration, including a heat exchanger, pump capacity and inlet sos, the lower part of the evaporator of each stage of distillation through a cube and the pump is in communication with the corresponding heat exchanger of the furnace of the next stage of distillation, the lower part of the evaporator of the last stage of distillation through a cube and pump is in communication with the last line of removal of the liquid fraction, which includes a refrigerator, a tank and an outlet connected in series pump. This allows you to ensure high quality of the obtained oil fractions, to obtain a large number of oil fractions with a narrow range of boiling start and end temperatures at one installation, and also to reduce the cost of production.

Description

The utility model relates to the petrochemical industry, in particular to small-tonnage plants for the simple distillation of complex high-boiling liquids, allowing the separation of oil and oil products into components called fractions.

A known installation for the processing of petroleum feedstock, consisting of a pre-heater and a fraction separator connected to a condenser, connected by a piping system with shutoff valves, while the fraction separator consists of three series-connected evaporators in which there are three stages of the separation of petroleum feed with three fractions of gasoline, kerosene-naphtha and solar, and three condensers, each of which is connected to one evaporator, forming three blocks (steps), vapor spruces and condensers are made in the form of one-way tubular heat exchangers and the upper part of the annular space of each of the evaporators is connected to the upper part of the annular space of the corresponding condenser by ducts tilted towards the condenser, while heaters are used as heaters in both evaporators and a preliminary heater, the upper part of each evaporator is connected to its annular space bypass pipe to prevent pressure in the pipe of the evaporator (see. RF patent for utility model No. 39886, IPC C 10 G 7/00, publication of 08/20/2004).

A disadvantage of the known installation is that the used tubular heat exchangers with small volumes of processed raw materials are susceptible to rapid coking and failure. The presence of preliminary electric heating of raw materials leads to an increase in energy costs and an increase in the total cost of processing. In general, heating raw materials and oil fractions with electric heaters leads to high energy costs and high production costs. The connection between the evaporator annulus and the condenser annulus

the heat transfer between them worsens the process of condensation of the oil fraction in the condenser and leads to an increase in the volume of refrigerant supply to the condenser, respectively, increases its costs and the cost of production. The absence of pumps between the evaporators reduces the overall productivity of the processing of raw materials known installation. The known installation does not provide for receiving at the same time more than three oil fractions.

Known oil refining station for dispersal of multicomponent mixtures containing a line for supplying an oil mixture and a line for the removal of liquid fractions, as well as two stages for dispersing the oil mixture in series, each of which includes a condenser and a heater for the oil mixture, in addition, the station additionally contains at least , one or more stages of dispersal of the oil mixture and successively installed on the oil mixture supply line heat exchangers, which are combined recuperative oil mixture heaters and coolers, as well as a pump and furnace for heating the oil mixture made in the form of a furnace for burning liquid or gaseous fuels, the upper part of the evaporator is connected by a pipeline to the condenser, and the lower part of the evaporator of each stage is connected via a valve device to the corresponding heat exchanger (see RF patent for utility model No. 17004, IPC V 01 D 3/00, publication March 10, 2001).

A disadvantage of the known station is the excessive number of heating stages - a furnace for heating the oil mixture and oil mixture heaters built into the evaporators in the form of furnace devices, which leads to high fuel costs for multiple heating of the oil mixture and, accordingly, an increase in the cost of the resulting oil products. The supplied petroleum mixture heated in the last and previous heat exchangers does not sufficiently cool the first finished fractions, which leads to their exit in a hot state and requires additional cooling to a temperature that allows their shipment to consumers, and, accordingly, to additional costs for coolers and increases the cost of production. In addition, the cooling in the recuperative heaters of the oil mixture depends on the ambient temperature, that is, it is not stable from the time of year and requires additional expensive measuring and control equipment.

The objective of the claimed utility model is to reduce the cost and ensure the high quality of the obtained oil fractions, to ensure the production of a large number of oil fractions with a narrow range of boiling start and end temperatures at one installation.

The essence of the utility model is as follows.

A hydrocarbon feed fractionation unit comprising a feed line, several stages of distillation and a line for removing liquid fractions, each stage of distillation comprising a furnace heat exchanger, an evaporator and a condenser connected to the pipes in series, to which a liquid fraction removal line is connected, including series connected a refrigerator, a storage tank, a pump, a tank and an output pump, a feed line is connected to the heat exchanger of the furnace of the first stage of acceleration, including the heat exchanger, the pump capacity and the inlet pump, the lower part of the evaporator of each stage of distillation through a cube and the pump is in communication with the corresponding heat exchanger of the furnace of the next stage of distillation, the lower part of the evaporator of the last stage of distillation through a cube and the pump is in communication with the last line of the liquid fraction, which includes serially connected refrigerator, capacity and output pump.

The technical result of the utility model is to increase the reliability of the installation, its compactness and efficiency, the possibility of obtaining narrow oil fractions,

The essence of the utility model is illustrated in the drawing, where figure 1 shows the installation of fractionation of hydrocarbons.

The hydrocarbon feed fractionation unit shown in FIG. 1 contains a feed line, three stages of distillation and four lines for removing liquid fractions. Each stage of the acceleration includes in series connected by piping heat exchanger 1 of the furnace 2, the evaporator 3 and the condenser 4, which is connected to the drain line of the liquid fraction. The liquid fraction removal line includes a refrigerator 5, a capacity 6, a pump 7, a capacity 8, and an output pump 9 connected in series. A feed line is connected to the heat exchanger 1 of the furnace 2 of the first stage of distillation. The feed line includes a heat exchanger 10, a pump 11, a tank 12 and an inlet pump 13.

The lower part of the evaporator 3 of the first and second stage of distillation through the cube 14 and the pump 15 is in communication with the corresponding heat exchanger 1 of the furnace 2 of the next stage of distillation.

The lower part of the evaporator 3 of the third stage of distillation through the cube 16 and the pump 17 is in communication with the fourth line of removal of the liquid fraction.

The fourth discharge line of the liquid fraction includes a series-connected refrigerator 18, a tank 19 and an output pump 20.

Installation works as follows.

Crude oil from the tank 12 is pumped 11 to the heat exchanger 1 of the furnace 2 after passing through the heat exchanger 10 heated by steam. The temperature of the oil supplied to the furnace rises by 40 ÷ 60 ° C.

In the heat exchanger 1, oil is heated to a temperature of 120-140 ° C, the resulting vapor-liquid mixture enters the evaporator 3, in which the vapor and liquid phases are separated and additional part of the volatile components is evaporated from the liquid phase due to the heat of overheating. The vapor phase of the gasoline fraction enters the condenser 4 (cooled by water), in which it condenses and partially cools, then further cooled in the refrigerator 5 with water to a temperature of no higher than 40 ÷ 45 ° С. The cooled liquid gasoline fraction flows into the tank 6, from which it is pumped out by the pump 7 into the storage tank 8 of the commodity and raw material park.

The liquid phase separated in the evaporator 3 accumulates in the cube 14, from which it is pumped 15 to the heat exchanger 1 of the furnace 2 of the second stage of acceleration, in which it is heated to a temperature of 190 ° C. The resulting vapor-liquid mixture enters the evaporator 3 of the second stage of distillation, in which the vapor phase is separated from the liquid and the liquid phase boils due to its heat of overheating. The resulting vapor phase of the kerosene fraction enters the condenser 4 and then to the refrigerator 5, cooled by water, respectively. The vapor phase condenses, and the formed and cooled liquid kerosene fraction flows into a tank 6, from which it is pumped into a storage tank 8 of a commodity-raw material park with a pump 7.

The liquid phase flowing from the evaporator 3 of the second stage to the cube 16 is supplied by the pump 17 to the heat exchanger 1 of the furnace 2 of the last stage. In the heat exchanger 1 oil, from which the gasoline and kerosene fractions are removed, is heated to a temperature of 320 ° C. The resulting vapor-liquid mixture enters the evaporator 3 of the last stage, separating it into liquid and vapor phases. Due to the heat of overheating in

the evaporator 3 from the liquid phase are allocated vapors of the diesel fraction. From the evaporator 3, the vapor phase of the diesel fraction enters the condenser and then into the refrigerator, cooled by water. After condensation of the vapors of the diesel fraction and cooling of the condensate to a temperature of about 50 ÷ 60 ° C, the latter flows into the storage tank, from where it is pumped into the tank of the commodity and raw material park.

From the evaporator 3 of the last stage of distillation, the liquid phase (fuel oil) flows into the cube, from where it is pumped to the heat exchanger 18 (cooled by water) from where it is fed into the storage tank 19 of the commodity-raw material park.

From storage tanks 8, 19, finished products are shipped by pumps 9.20 to consumers.

The claimed utility model allows to ensure the high quality of the obtained oil fractions, to obtain a large number of oil fractions with a narrow range of boiling start and end temperatures at one installation, and also to reduce the cost of production. The nomenclature and design of the main technological equipment, which is part of the individual stages, is the same, which makes it possible to unify the stages and simplify the supply and installation, to complete the number of stages necessary for production and, accordingly, the number of oil fractions obtained simultaneously.

Claims (1)

A hydrocarbon feed fractionation unit comprising a feed line, several stages of distillation and a line for removing liquid fractions, each stage of distillation comprising a furnace heat exchanger, an evaporator and a condenser connected to the pipes in series, to which a liquid fraction removal line is connected, including series connected a refrigerator, a storage tank, a pump, a tank and an outlet pump, a raw material supply line is connected to the heat exchanger of the furnace of the first stage of acceleration, including the heat exchanger, the pump, the tank and the inlet pump, the lower part of the evaporator of each stage of distillation through a cube and the pump is in communication with the corresponding heat exchanger of the furnace of the next stage of distillation, the lower part of the evaporator of the last stage of distillation through a cube and the pump is in communication with the last liquid discharge line, which includes a refrigerator, a tank and an output pump connected in series.