SU1505956A1 - Composition for control of asphalt-resin-paraffin deposits - Google Patents

Abstract

The invention relates to asphalt-resin-paraffin deposits (ARP) for the extraction of oil and can be used to remove and prevent the formation of ARP in the bottomhole formation zone and oil-field equipment. The goal is to increase the efficiency of dissolving and dispersing ARPD. The composition contains, in wt.%: VAT residue production of butyl alcohol and 2-ethylhexanol 70-85

toluene fraction 15-30. The toluene fraction with a toluene content of at least 97% is obtained by the rectification of bentol, a by-product in the production of ethylbenzene. The composition is prepared by simply mixing the components in predetermined ratios under factory conditions. The composition is far superior to the known detergent-dispersant properties. 3 tab.

Description

The invention relates to the extraction of oil and can be used to remove and prevent the formation of asphalt-resin-paraffin deposits in the bottom-hole formation zone, production systems, collection, transportation and storage of oil.

The aim of the invention is to increase the efficiency of dissolution and dispersion of asphalt-resin-paraffin deposits.

  The asphalt-smoloparaffin deposits (ARPD) in the oilfield equipment based on the bottoms of the production of butyl alcohol and 2-ethylhexanol by the method of oxosynthesis additionally contains a Toluene fractionation with the following ratio of components, wt.%:

VAT residue of production of butyl alcohol and 2-ethylhexanol 70-85 Toluene

fraction 15-30

The components indicated are: the toluene fraction and the bottoms from the production of butyl alcohols and 2-ethylhexanol (RSPS and 2TG) are O1

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with petrochemical products, and KOPBS and 2EG - production waste. The main part of which is burned, and the toluene fraction is used to prepare the catalyst complex. A fraction is obtained in the production of ethylbenzene by rectification of a by-product of bentol. The toluene fraction is co6oii to the main toluene with a small admixture of other hydrocarbons.

The average composition of the toluene fraction, wt.%:

Paraffin

hydrocarbons 0,89-1,0 Benzene1,2-1,5

Toluene 96,8-98,4

Ethylbenzene 0.1-0.2 Styrene0.2-0.5

Ingredient of the composition - the bottoms of the rectification of hydroforming products after the cobalt regeneration stage is a technical mixture of products of two separate technological processes united by a single reservoir park and a communication system. KOPBS in the amount of 18–12% and distillation residues of 2EG production from oil aldehydes and hexanoic acid in the amount of 78–84% are fed into one container in the balance ratio.

COPBS and 2EG have the following component composition, wt.%: 1 T-aldehyde aldehyde 0.97 n-butyraldehyde Butyl alcohol 2.50 n-Butyl alcohol 9.47 i-Butyl formate 0.19 n-Butyl formate 0.21 Alcohols Cg-C, 2. 30,0 Butyl butyrates 16,0 Dimers, trimers

oily aldehydes 35.0 Physical and chemical properties of the composition are as follows:

ABOUT

Density at 20 s, kg / m 897-899

Kinematic viscosity, mm / s 1, Temperature, С:

congestion -70 flash32-34

Table 1 shows the physico-chemical properties of the asphalt-resin-paraffin deposits and oils used in the experiments; Table 2 shows the results of the effectiveness tests

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struggle with ARPD known compositions, in table 3 - the effectiveness of the struggle with ARPD known and proposed compositions with different ratio of components.

The composition is prepared as follows.

In a flask with a stirrer, COPPS and 2EG, taken from a special container from the production of butyl alcohols, are loaded, and the toluene fraction is added. Stirring is carried out under tight conditions for 5 minutes at room temperature until complete dissolution. The ingredients of the composition are metered by weight.

Example 1. Take 15 g of the toluene fraction and 85 g of a mixture of bottoms of COPPS and 2EG. The mixture is stirred with a laboratory stirrer for 5 at. Then, the presence of two phases is recorded visually in transmitted light. In the absence of an interface and the appearance of a uniform color (yellow-brown), the composition is considered prepared. Get sample 1.

PRI mme R 2. Take 20 g of the toluene fraction and 80 g of COPCH and 2EG. The mixture was prepared as in Example 1, sample 2 was prepared.

The effectiveness of the formulations and reagents prepared is determined by the effect on the sediments taken from oil producing wells, which have different physicochemical properties. The versatility of the composition is evaluated by two effects: the ability to dissolve ARP from a metal surface over time and the ability to inhibit the formation of ARPD. Evaluation of compositions as inhibitors of AFS is carried out according to the generally accepted method - a test for detergency according to two indicators: according to the degree of washing of the oil film with the studied compositions and according to the average value of the dispersion of AFS in the medium of these compositions. In the case of an oil film washing test, the percentage of oil film washing off with formation water from the glass tube wall is determined by time (half the entire surface of the tube is calculated as 100%).

Having washed off, it is customary to consider an excellent 80-90% for 30 s, a good 70-907, for 60 s, a satisfactory 70-90% for 180 s.

When testing for), the size of the resulting particles of sediment n riJiacToFiou water is added when adding the test reagent. Retulta is considered to be excellent when the particle size of the sediment is 0.1–3 mm (100%), good is 0.1–5 mm (100%), satisfactory is 0.1–7 mm (100%), unsatisfactory - the top 7 mm Moreover, the reagent that gives such a dispersion of sediments is rejected and is not considered as an inhibitor of LSPO.

Determination of the degree of washing is captured (and the oil is carried out as follows. Pour 20 ml of the test oil into glass tubes and incubate for 30 minutes to create a film of oil on the tube surface. Then the oil from the tubes is poured and the water from the same field is poured into them and oil, in the amount of 10 ml each and incubated for 1 minute. After that, 10 ml of oil, previously well mixed with the proposed composition, are introduced into each tube (the content of the composition in all experiments is 0.02 wt.%). The tubes are closed with stoppers and inverted . Through The test tube surface free from the oil film is determined visually in percent. Similarly, a control experiment is carried out without applying the composition. The effectiveness of the test compositions for washing the oil film is estimated from the difference between the initial surface and the surface that was freed from the oil film in this and control experiments. .

Tests to determine the particle size of the dispersion in the medium of the proposed composition of sediment deposits selected from producing paraffin-containing sediments of oil wells are carried out in the following sequence. Using a measuring cylinder, take 50 mm of produced water and pour it into a conical flask, where the proposed composition is then . Next, in this flask is placed a portion of 2.5 g ARPD. The contents are heated on a hot plate to completely melt the deposits. The flask is then cooled under running tap water, shaking it in a circular motion. In this case, the dispersion of ARPD is visually recorded. The proposed formulation is administered in an amount of 0.02 mA.

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(llIX lPJIfMIHC 1 (K, HHI-I l. 1H 11G UD.CH R iyu L (L11) ngoiid g ((. R glass 111n, 1e cones smkggych) see pour gspsh s. Ja reload the cones of the pressure pan)) If the evaporation crucible is molded into the field under investigation. The crucible is sedimentally heated until it is completely melted on the electric stove of the closed type. 1. The melt of the SLF is lowered by the ready-made metal plate (10x20x1 mm) ) for 3 s, holding the middle of the plate for 5 with tweezers. Then

the plate is taken out when the plate with the deposited layer of paraffin coating with a special holder, filled in a rubber stopper, is poured into a flask with 0 test composition and include a stopwatch. After 15 min, the effect of the composition on the coating is observed visually, the first measurement is recorded. Then measurements are carried out in 1 hour to 3 hours and after 5-6 hours and so on with each flask. For another field, the experiments are repeated. Image II) I in a flask is suspended vertically without stirring at room temperature.

0 Under industrial conditions, the composition is prepared at a chemical plant in a commodity tank according to the project at ambient temperature by mixing KOPBS and 2EG with a toluene fraction in predetermined ratios.

Claims (1)

The composition has good detergent-dispersant properties and is much more effective in combating LSPO than the known compounds. Invention Formula The composition for controlling asphalt-paraffin deposits in oilfield equipment based on the bottom residue of the production of butyl alcohol and 2-ethylhexanol by the method of oxo-synthesis, differs in that it also contains a fraction containing not less than 97% toluene, in the following ratio of components, wt.h.: Vat residue from the production of butyl alcohol and 2-ethylhexanol 70-85 Toluene fraction, containing at least 97% toluene13-30 0 five 0 f o o o h "h" h - o l-J- - oOCN | r4O (N LOLnU lJ lOLnLOLn fLn about COvOOO- -cfOOvDOf- rOCriinLOvDOOCNl J-LO - rLOr irorocMcNLn tm O OLrl SChGOt- CT - u-ir- o-ivor- - romocN ) -COCNl} -r 4DCr rsl 4D IT-CNJ, - 4D ttNlr-cr .NCNI - u-iO CNr moOON4DOOLnu ir GO ro cG LO CHO - SL) --t CN P1- J3 in r O -J-OO O GO CNI - SCO OO LriLTiT-hDlpocmootN | ±  - -CNlcNOOC O - CNI  - OrOvoocNjm o l X: vOCOOO -O- r cO ocooooooooc a a ooco ovioc-inor fO - t g - hOr-hOr hOr H Ln r Г I rчlCOO t - 1-г-.) - southwest, G-. t P | GO CM g-st about gh r4Orol-d- t O tLn4D f OOvOCO J-OC 3Ln f O- | T- (v-ir-chtooogoozoo O rocN tr 4mcNrO - - n rsl-cfrOvC - t tCTiOO r oromoo t4DrocT co h) Yu l CM Ch a CM CHO - u-irOCNlCOOOv rNjr rcX3 LTirO - (TioOoO .- .oo CM4Or C3 CMt frO T : waai-, t: tWF6cn