RU2075495C1 - Method of producing petroleum coke - Google Patents

Abstract

FIELD: petroleum processing. SUBSTANCE: in a method consisting in heating raw material, separating it into light fractions and heavy residue, heating the latter followed by its coking and withdrawal of vapor-liquid coking products and coke, the distinguishing features are as follows. Separation of raw material into light fractions and residue is carried out in evaporator, the light fractions being further fractionated in rectification column in common with vapor-liquid coking products. If necessary, after separation is completed, raw material is combined with fractionation bottoms. EFFECT: increased yield of coke with specified sulfur content, reduced power consumption, increased turnaround time. 2 cl, 2 tbl

Description

 The invention relates to the field of oil refining, in particular to methods for producing high-quality electrode and anode cokes from sulfur materials.

A known method of producing petroleum coke, including heating the feedstock, feeding it into a distillation column for mixing with the condensed heavy portion of the vapor-liquid coking products (recirculate) with the formation of a heavy residue and fractionation of non-condensed vapors, heating the heavy residue and its subsequent coking [1]
Closest to the claimed object is a method of producing petroleum coke, including heating the feedstock, feeding it to a distillation column for mixing with the condensed heavy portion of the vapor-liquid coking products (recirculate) with the formation of a heavy residue and fractionation of non-condensing vapors, heating the heavy residue and its subsequent coking [ 2]
The disadvantages of the methods, both by analogy and by the prototype, are low coke yield, high energy intensity due to the return of vapor-liquid coking products to the distillation column. In addition, the transfer of coke particles together with the foam into the distillation column, and then into the furnace, promotes coking of the equipment and, accordingly, to reduce the overhaul distance of the installation. In addition, together with the vapor-liquid coking products, additional sulfur enters the distillation column where the raw materials are formed, increasing the sulfur content in the obtained coke, which is especially undesirable when producing electrode coke in which the sulfur content should not exceed 0.8% And since this the technology does not allow to regulate the amount of supplied vapor-liquid coking products, this does not make it possible to obtain coke with a given sulfur content, does not allow to optimize the process.

 The invention is aimed at increasing the yield of coke, reducing energy consumption, increasing the turnaround path of the installation, obtaining coke with a given sulfur content.

 This is achieved by the fact that in the method for producing petroleum coke, which includes heating the feedstock, separating it into light fractions and a heavy residue, heating the latter and subsequent coking with the removal of vapor-liquid products and producing coke, separating the feedstock into light fractions and a heavy residue is carried out in an evaporator while the light fractions are subjected to fractionation in a distillation column together with vapor-liquid coking products. If necessary (for example, upon receipt of anode cokes, where the sulfur content can reach 2%) after separation, the raw materials are mixed with the bottom residue obtained by fractionation.

 The drawing shows a diagram of the proposed method for producing petroleum coke.

 The method is as follows.

The feedstock is heated in a tube furnace 1 to a temperature of 350 ^o C and sent to the evaporator 2 to separate it into light fractions and heavy residue. The latter is heated in a tube furnace 3 to temperatures of 480 505 ^o C and subjected to coking in the reactors 4, of which vapor-liquid coking products are sent to distillation column 5, which also serves light fractions formed in the evaporator 2. Light fractions are removed from the top of column 5, with bottom bottoms, which when using distillate raw materials are removed from the installation, and when using residual raw materials are added as recycle to the raw materials.

 The proposed method was tested on a pilot installation. As raw materials, distillate cracking residue and tar were used. The characteristics of the raw materials are given in table. one.

Example 1. The distillate cracking residue was heated to 370 ^° C. and fed to an evaporator to separate into light fractions and heavy residue. The residue was heated to 500 ^° C. and fed to a coking reactor. Steam-liquid coking products from the reactor were fed to a distillation column, which also received light fractions from the evaporator. Light fractions are removed from the top of the distillation column, and bottom residue from the bottom. Coking conditions, coke yield and sulfur content are presented in table. 2.

 Example 2. The same raw material, under the same conditions, was subjected to coking, with the only difference being that the bottom residue from the distillation column was fed to the evaporator as recycle. The data of the example are also summarized in table. 2.

Example 3 (prototype). The same raw materials as in examples 1 and 2 were heated to 370 ^° C. and fed to a distillation column for mixing with the condensed part of the vapor-liquid coking products supplied from the reactor and separating the mixture into light fractions and bottoms. The bottom residue was heated to 500 ^° C. and coked in a reactor. The data are summarized in table. 2.

 Example 4, 5, 6 was carried out analogously to examples 1, 2 and 3, respectively, but tar was used as raw material. All data are summarized in table. 2.

 Examples 1 to 3 relate to methods for producing coke for the production of electrodes in the electric steel industry, where the sulfur content is the determining indicator (not> 0.8%). As can be seen from the table, the use of the proposed method will allow, in comparison with the prototype, to reduce the sulfur content in coke to 0.6 0.7%. In addition, the yield of coke increases compared to the prototype by 1.4 1.8 times.

 Examples 4 to 6 relate to methods for producing coke used in the aluminum industry, where the sulfur content of coke can reach 2%, i.e. from the table we can conclude that the coke obtained by the proposed method satisfies the requirements of the consumer, and its output is increased in comparison with the prototype in 1.6 2 times.

 In addition, the above examples 1 to 6 indicate that the proposed method will allow to obtain coke of a given quality by optimizing the process.

 With regard to energy consumption, in the proposed method, the energy consumption per unit of coke produced (reduced energy consumption) compared with the prototype is reduced by 1.3 to 1.4 times.

 It should be noted that in the case of transfer of foam from coking reactors in the proposed method, coke particles enter the coking raw material in a much smaller amount than in the prototype (in the case of using recirculate), or do not fall at all (in the case of coking of light raw materials without using recirculate) . In the method according to the prototype, when transferring foam from coking reactors, coke particles enter the lower part of the distillation column, whence they are received by the furnace pump and into the reaction furnace, which leads to their coking.

 Thus, the use of the proposed method will reduce the coking of the furnace coils, increase the service life of the furnace pumps and thereby increase the overhaul distance of the installation.

Claims (2)

 1. A method of producing petroleum coke, including heating the feedstock, separating it into light fractions and a heavy residue, heating the latter and its subsequent coking with the removal of vapor-liquid products and producing coke, characterized in that the separation of the feedstock into light fractions and a heavy residue is carried out in an evaporator while the light fractions are subjected to fractionation in a distillation column together with vapor-liquid coking products.  2. The method according to claim 1, characterized in that after separation, the raw materials are mixed with the bottom residue obtained by fractionation.

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