RU2202730C2 - Method of transportation of viscous oils and oil products with high content of asphalt-resinous substances over pipe- line - Google Patents

Abstract

FIELD: pipe-line transport of oil. SUBSTANCE: method of transportation of high-viscosity oils includes injection into oil of block copolymer based on glycols of general formula H(C₂H₄O)_n(C₃H₆O)_mOAO(C₃H₆O)_m(C₂H₄O)_nH,, where A = -C₂H₄- or -C₃H₆-, n=14-16, m=24-27 with molecular weight 4300 arbitrary units in mixture with polyalkylbenzene resin-by-product of production of isopropylbenzene in ratio of block copolymer to polyalkylbenzene resin 1: 1-4. Ethylbenzene or butylbenzene of isopropylbenzene fractions can by used in the capacity of solvent. Method is efficient for trasportation over pipe-line of viscous oils and oil products with content of water from 0 to 3% and increased content of asphalt-resinous substances thanks to reduced viscosity of transported products. EFFECT: raised efficiency of method. 2 cl, 2 dwg, 7 tbl

Description

 The invention relates to the field of pipeline transport of oil and oil products and is intended for transportation of highly viscous oil.

Existing methods of pipeline transport of high-viscosity oil can be divided into several groups:
1) methods based on pumping oil through a low-viscosity near-wall layer. Moreover, this wall layer can be created both with the help of water with the addition of surfactants, and with the formation of a low-viscosity oil-in-water emulsion.

 In the patent of the Russian Federation 2105923, F 17 D 1/16, 02.27.98, BI 6, a method is described for pipeline transportation of high-viscosity oils using a high molecular weight oil component as an ozone oxidation product. Oil treatment with ozone is carried out before mixing it with water. As a result of the ongoing reaction, oxygen-containing compounds accumulate in the oil volume, which give the oil a high surface activity at the border with water, as well as the ability to form low-viscosity emulsions of the direct type.

 The disadvantage of this method is the formation of oil-water emulsions during transportation, increased costs for the subsequent process of dehydration and additional operating costs for special equipment for producing ozone.

A known method of transporting highly viscous oils (AS USSR 767451, F 17 D 1/16, 09/30/80, BI 36, with the additional invention of AS USSR 1260632, F 17 D 1/17, 09/30/86, BI 36) under conditions of creation in a pipeline peripheral annular flow from an aqueous solution of a mixture of nonionic surfactants. Sulfonol NP-2, sulfonate, DB wetting agent and 2-hydroxy-1,3-diaminopropane-N, N, N ¹ , N ¹ -tetraacetic acid are used as surfactants.

 However, the peripheral annular stream used in this method from an aqueous solution of a surfactant mixture promotes the formation of oil-water emulsions, which is extremely undesirable when transporting oil that does not contain water. The formation of a water-oil emulsion creates the problem of its destruction and requires an appropriate hardware solution of the process.

 2) methods in which an increase in the transport efficiency of the pumped oil is achieved by lowering its pour point by introducing various surfactants.

 So, in the method for preparing high-viscosity paraffin oil described in the USSR AS 987277, F 17 D 1/16, 01/01/83, BI 1, a mixture of selective solvents in the form of nitrogenous surfactants and wetting agents is used as a reagent to improve the rheological properties of oil. The oil containing the reagent is transported to the preparation point, where it is subjected to heat treatment.

There is also known a method of preparing and transporting high-viscosity oils and petroleum products by pipeline (AS USSR 1451434, F 17 D 1/17, 01/15/89, BI 2), in which aluminum hydroxydicarboxylates are introduced into heated oil based on naphthenic acids of industrial fractions of synthetic fatty acids C _17-20 ; C _18-23 , C _10-16, or C _10-18 fatty acids.

 The disadvantage of these methods is the use of heat treatment of oil at the stage of its preparation for transportation, which increases the energy consumption and the cost of the process.

The closest in technical essence is the USSR AS 1527451, F 17 D 1/17, 12/07/89, BI 45, which describes a method for preparing and transporting heated high-viscosity oils and oil products through a pipeline using block copolymers of ethoxylated alkyl phenols of the neonol type AF ₉ -12 in an amount of 0.1-0.2 vol.%.

 The disadvantage of this method is the use of heat treatment of oil at the stage of its preparation for transportation, which increases the energy consumption and the cost of the process and relatively low efficiency, which is confirmed by the amount of surfactant used.

 The objective of the invention is to develop an effective method for transporting pipelines of viscous oils and petroleum products with a water content of 0-3% and a high content of asphalt-resinous substances by reducing the viscosity of the transported products.

The problem is solved by the development of a method for transporting high-viscosity oils, including the introduction of a block copolymer containing ethylene oxide into the oil. Moreover, as a block copolymer, a block copolymer based on glycols of the general formula
N (C ₂ H ₄ ) _n (C ₃ H ₆ O) _m OAO (C ₃ H ₆ O) _m (C ₂ H ₄ O) _n H,
where A = —C ₂ H ₄ - or —C ₃ H ₆ -;
n = 14-16, m = 24-27 with a molecular weight of 4300 cu

 mixed with polyalkylbenzene resin - a by-product of the production of isopropylbenzene in the ratio of block copolymer: polyalkylbenzene resin 1: 1-4.

 The problem is also solved by the fact that a mixture of block copolymer (BS) and polyalkylbenzene resin (PABS) can be introduced into the oil stream in a solvent in a ratio of 1: 1, ethylbenzene or butylbenzene or isopropylbenzene fractions can be used as a solvent.

In the table. 1 shows the physico-chemical parameters and properties of the block copolymer of ethylene oxide and propylene oxide based on glycols-Reapon-4V (P-4B) - the General formula
N (C ₂ H ₄ O) _n (C ₃ H ₆ O) _m OAO (C ₃ H ₆ O) _m (C ₂ H ₄ O) _n N, where A = -C ₂ H ₄ - or -C ₃ N ₆ - and n = 14-16, m = 24-27, manufactured according to TU 6-55-54-91.

 In the table. 2 shows indicators characterizing the quality of a polyalkylbenzene resin, a by-product of the production of isopropylbenzene, consisting of a mixture of di-, tri-, tetra-isopropylbenzenes and other higher molecular weight polyalkylbenzenes sold under the trade name polyalkylbenzene resin (PABS) in accordance with TU 33.10296-83.

 The use of a composition in the form of a solution in an alkylbenzene fraction (ALBP): an ethylbenzene fraction (EBP) or an isopropylbenzene fraction (IPBP), or a butylbenzene fraction (BBP) in a 1: 1 mass ratio is associated with technological requirements for reagents used in the field for solidification temperature and viscosity. Ethylbenzene fraction is produced according to TU 6-01-10-37-78, isopropylbenzene fraction - according to TU 38.402-62-140-42, butylbenzene fraction - according to TU 38-10297-78.

 In the table. 3 presents the characteristics of the studied oil of the Demkinsky field of the Bobrikovsky horizon of well 628.

 The method using a mixture of BS and PABS is as follows.

 Example. 0.04 ml of reagent solution is introduced into 100 g of oil, the oil and reagent are intensively mixed for several minutes. Then the sample is placed in a cell of a rotational viscometer of the Reotest-2 type and its rheological characteristics are determined. Studies are carried out of the rheological properties of "pure" oil and oil in the presence of a reagent. The results of the study are presented in table. 4.

 The study of the rheological characteristics of oil in the presence of other composite mixtures is carried out similarly to the above example. The research results are presented in table. 5-7 and in FIG. 1 and 2.

 In laboratory conditions, the effectiveness of the proposed method using a mixture of BS and PABS was evaluated by rotational viscometry by the value of the effective viscosity of the oil depending on the applied shear stresses.

In the description of the invention, selected as a prototype, the initial parameters of the studied oils are given. Judging by the characterization of the pour point, it can be assumed that these oils have a high content of solid paraffins. The table does not specify the temperature at which the viscosity of the oils was determined. It is obvious that, having such a high pour point, oil cannot have such low viscosity values at a temperature of 20 ^o C. Apparently, in this table the viscosity of the oils is indicated at the temperature of the studies, i.e. at T = 50-60 ^o C. The introduction of the reagent - ethoxylated alkyl phenol - allows to lower the pour point of oils. It can be assumed that the mechanism of action of the reagent is based on the prevention of the formation of large paraffin crystals. In this case, the reagent molecules can either be paraffin crystallization centers themselves, which leads to the formation of mainly small paraffin crystals, or be adsorbed on the surface of paraffin crystals and prevent their adhesion. Both of these processes allow you to change the pour point of the oil after heat treatment, in this case, the pour point is reduced, and to reduce the dynamic viscosity.

 From the table. Figure 3 shows that the oil used in the experiments has a slightly different composition: resins and asphaltenes predominate in the oil of the Demkinsky field. Therefore, the mechanism of action of the introduced reagent will be different.

Individual reagents were tested at a temperature of 20 ^o C. The viscosity of oil without a reagent under these conditions is not too high and lies in the range of 260-200 cP depending on the shear rate. With the introduction of P-4B and PABS, the viscosity of the oil decreases by 20-40 cP (see table. 4).

In FIG. 1 shows the dependence of the dynamic viscosity η, cP, oil of the Demkinsky field at a temperature of 20 ^o C on shear rate γ, 1 / s, with the introduction of composite compositions in an amount of 0.04 vol.%, Where row 1 is the dependence of the dynamic viscosity of oil on shear rate without introducing the composition, row 2 is the same with the addition of R-4B-PABS in the ratio 1: 1, row 3 is the same with the addition of R-4B-PABS in the ratio 1: 4. From the table. 5 and FIG. Figure 1 shows that when R-4B and PABS reagents are mixed at a ratio of 1: 1, the oil viscosity decreases by 50 cP, with an increase in the proportion of PABS in the composition to 80 wt.%, The composition efficiency increases, a synergistic effect is observed, as evidenced by a decrease in oil viscosity up to 130 cP, i.e. more than 50%.

It should be noted that the study of the dynamic viscosity of oil in the presence of composite compositions was also carried out at a temperature of 10 ^o C in order to obtain information about the effect of the composition at a reduced temperature, characteristic of the winter period of operation.

In FIG. 2 shows the dependence of the dynamic viscosity η, cP, oil of the Demkinsky field on the shear rate γ, 1 / s, with the introduction of compositional compositions of the P-4B-PABS series in a different ratio in the amount of 0.04 vol.% At a temperature of 10 ^o C, where 1 - dependence of the dynamic viscosity of oil on shear rate without introducing the composition, row 2 is the same with the addition of the composition in a ratio of 1: 4, row 3 is the same with the addition of the composition in the ratio 1: 6, row 4 is the same with the addition of the composition to 1: 8 ratio.

As can be seen from the table. 6 and FIG. 2, an increase in the proportion of PABS to a ratio of 1: 8 leads to a decrease in the effectiveness of the composition, although compositions with a ratio of 1: 6 and 1: 8 can also reduce the viscosity of the test oil at 10 ^o C. According to the results of this experiment, the ratio of the claimed composition was 1: 4 defined as optimal.

 It is known that resinous-asphaltene substances are characterized by exchange, dipole-dipole interactions, and hydrogen bonds. Under certain conditions, the total effect of intermolecular forces arising between arene fragments contained in the composition of asphaltenes and resins, carboxyl and amino groups leads to the so-called stacking interaction, which is responsible for the formation of their packet crystal-like structure / Z.I.Sunyaev, R.Z. Safieva , R.Z. Syunyaev Oil dispersed systems. - M .: Chemistry, 1990 .-- 226 p. /. The introduction of surfactants allows you to change the intermolecular interactions in the liquid and reduce the degree of association of resinous-asphaltene substances. As a result of changes in the nature of intermolecular interactions, there will be a change in the structural and mechanical strength of the dispersed phase and, as a result, a decrease in the viscosity of the studied oil.

 For the composition of Reapon-4V-PABS (1: 4), the optimal consumption of reagent for oil was determined. The data are presented in the table. At a flow rate of 400 g / t (0.04 vol.%) There is a noticeable decrease in viscosity to 530 cP. With an increase in reagent consumption, the viscosity decreases more effectively, with the introduction of the composition in an amount of 800 g / t (0.08 vol.%), The oil viscosity decreases by 2 times and reaches a value of 430 cP (see table. 7).

 The data, in particular, a sharp decrease in reagent consumption (from 0.1-0.2 vol.% Of the prototype to 0.04-0.08 vol.% In the proposed method) and the absence of heating of oil indicates that the effectiveness of the proposed method is higher than that of the known.

Claims (3)

1. A method of transporting highly viscous oils, comprising introducing into the oil a block copolymer containing ethylene oxide, characterized in that a block copolymer based on glycols of the general formula is taken as a block copolymer
Н (С ₂ Н ₄ О) _n (С ₃ Н ₆ О) _m ОАО (С ₃ Н ₆ О) _m (С ₂ Н ₄ О) _n Н,
where A is —C ₂ H ₄ - or —C ₃ H ₆ -;
n is 14-16;
m = 24-27,
with a molecular weight of 4300 cu mixed with polyalkylbenzene resin - a by-product of the production of isopropylbenzene in the ratio block copolymer: polyalkylbenzene resin 1: 1 ÷ 4.  2. The method according to claim 1, characterized in that the mixture of block copolymers based on glycols and polyalkylbenzene resin is introduced into the oil stream in a solvent in a ratio of 1: 1.  3. The method according to claim 1, characterized in that the solvent used is ethyl, or butyl, or isopropylbenzene fractions of the production of phenol and acetone.

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