RU2139424C1 - Compound and method for producing reagent for cross-linking solutions of polysaccharides - Google Patents

Abstract

FIELD: oil and gas production industry. SUBSTANCE: water solutions of polysaccharides are used in oil and gas production industry for producing sand-carrying liquids used in hydraulic fracturing of bed. Compound and method for production of reagent provide for mixing of decahydrate tetraborate of sodium and glycerine with subsequent adding of alkali in following proportion of components, mas. %: decahydrate tetraborate of sodium 15-25, glycerine 35-70, 5-40% water solution of sodium or potassium hydroxide 55-50. Additionally introduced into thus produced solution is chrome-potassium alum or chrome acetate in amount of 1-50 g/kg. Application of aforesaid compound and method simplifies technological process, improves rheological properties both at 20 C and at higher temperatures. EFFECT: higher efficiency. 23 cl, 3 tbl, 10 ex

Description

 The present invention relates to the oil and gas industry, in particular, compositions and methods for preparing reagents for producing water-based sand carriers for hydraulic fracturing.

 Sand-based fluids based on aqueous polysaccharide solutions are known, where boron-containing compounds are used as crosslinkers: alkali and alkaline earth metal borates - US Pat. No. 4,619776, E 21 B 43/26, 1986.

 The disadvantage of these crosslinkers is that they must be introduced into the polysaccharide solution in dry form, while the poor solubility of boric acid salts in water does not allow the crosslinking process to be carried out when the gel is injected into the formation, which significantly complicates the hydraulic fracturing process, because . the high structural viscosity of the resulting gel makes it difficult to mix with propanate.

Closest to the technical nature of the present invention is a method of preparing a crosslinker, allowing to obtain a thermostable gel on the stream when it is injected into the well, US patent N 625660, E 21 B 43/26, 1992 (prototype). In this case, as a crosslinker, a composition is prepared as follows: 130 parts of ten-sodium tetraborate are added to 300 parts of a 40% aqueous glyoxal solution. 65 parts of a 25% alkali solution are added to the resulting suspension to obtain a pH in the range of 4.9 to 6.5, and then 71.4 parts of a 70% aqueous sorbitol solution, after which the solution is heated to 95 ^° C and held within 3 hours, while the color of the solution changes from yellow to amber. After cooling, the pH of the resulting complex is in the range from 4.5 to 5.0. Then the resulting complex is additionally diluted with glyoxal and 25% sodium hydroxide in the following proportion: 41.6-55.5% vol. The initial cooked complex, 41.6-278 vol. % Glyoxal and 16.7 vol.% 25% sodium hydroxide solution.

 The disadvantages of the above method and composition are the high cost of the reagents used, such as glyoxal and sorbitol, as well as the complex preparation technology that requires exposure to heating for 3 hours and subsequent dilution of the resulting complex, as well as insufficient rheological parameters of the resulting polysaccharide gel.

The objective of the invention is:
1) Obtaining a crosslinker without the use of scarce and expensive reagents.

 2) Simplification of the technology for producing a stapler.

3) Obtaining a crosslinker, the use of which will allow you to get a more structured polysaccharide gels with high rheological properties both at a temperature of 20 ^o C, and at elevated temperatures.

The problem is solved in that the composition for the preparation of a reagent for crosslinking aqueous solutions of polysaccharides, including ten-sodium sodium tetraborate, an organic solvent and an aqueous alkali solution, contains glycerin as an organic solvent, and a 5 - 40% hydroxide solution as an alkali aqueous solution sodium or potassium, and additionally - potassium alum or chromium acetate in the following ratio of components, wt.%:
Sodium tetraborate ten - 25 - 25
Glycerin - 35 - 70
5 - 40% aqueous solution of sodium or potassium hydroxide - 5 - 50
chrome potassium alum or chromium acetate 1-50 g per 1 kg of a solution of ten-sodium tetraborate, glycerol and sodium or potassium hydroxide.

 The problem is also solved by the fact that in the method of preparing the reagent for crosslinking aqueous solutions of polysaccharides, which includes preliminary mixing of ten-sodium sodium tetraborate with an organic solvent followed by the addition of an aqueous alkali solution, ten-sodium sodium tetraborate is mixed with a solvent glycerol, an aqueous alkali solution of 5-40 is added % solution of sodium or potassium hydroxide, and then chromium potassium alum or chromium acetate is additionally introduced into the resulting true solution.

Ten-sodium sodium tetraborate (borax) is a solid crystalline substance - a colorless powder with the following physicochemical properties:
Density at a temperature of 20 ^o C - 1730 kg / m ³ ,
Solubility in water at a temperature of 20 ^o C - 75 g per 100 g of water.

Glycerin is a colorless viscous liquid with the following physicochemical characteristics:
the density of glycerol at a temperature of 20 ^o C - 1260 kg / m ³ ,
solubility in water - soluble in water in any ratio.

Sodium hydroxide - alkali, is a solid substance, colorless crystals, is available in the form of Czechs or granules, as well as in the form of a solution, has the following physicochemical characteristics:
Density at a temperature of 20 ^o C - 2130 kg / m ³
Solubility in water at a temperature of 20 ^o C - 109 g per 100 g of water
Potassium hydroxide - alkali, is a solid substance, colorless crystals, is available in the form of flakes or granules, as well as in the form of a solution, has the following physicochemical characteristics:
Density at a temperature of 20 ^o C - 2040 kg / m ³
Solubility in water at a temperature of 20 ^o C - 112 g per 100 g of water
Potassium alum is a solid substance - violet crystals, have the following physicochemical characteristics:
Density at a temperature of 20 ^o C - 1830 kg / m ³
Solubility in water at a temperature of 20 ^o C - 24.4 g per 100 g of water
Chromium acetate is a solid crystalline substance, is available in the form of a solution, has the following physicochemical characteristics: - 1300 kg / m ³
In contrast to anhydrous sodium tetraborate, sodium ten tetraborate dissolves in glycerol. Dissolution in glycerol occurs with an increase in temperature, which also contributes to dissolution. But ten-sodium sodium tetraborate also dissolves in alkali solutions, therefore, the addition of an aqueous alkali solution to the suspension of glycerol and ten-sodium sodium tetraborate makes it possible, on the one hand, to easily switch from the suspension to the true solution and, on the other, to reduce the viscosity of the system and simplify its mixing.

 As a result of mixing and the reactions occurring as a result of this, a colorless mobile liquid is obtained, which also has a low freezing point, which is important for the hydraulic fracturing process in winter.

 The lower limit of the concentration of sodium tetraborate tetraborate is due to the sufficient content of boron in the crosslinker, because a smaller amount leads to an increase in the crosslinker consumption upon receipt of hydraulic fracturing fluid, and the upper limit is caused by the solubility of sodium ten-tetraborate in a solvent system: glycerin is an alkali, above which crystals of ten-tetraborate may precipitate from the crosslinker solution.

 The lower limit of glycerol content is due to the solubility of sodium tetraborate, salt crystals can be precipitated below this limit, and the alkali must be added to the solution to dissolve the sodium tetraborate and reduce the viscosity of the resulting solution.

 The lower limit of the alkali content in the crosslinker is due to the solubility of sodium tetraborate, and the upper limit of the alkali content is determined by the pH level that is achieved when the crosslinker is added to the polysaccharide solution - not higher than 10, because at a higher pH, crosslinking is impaired.

The introduction into the composition of the crosslinker of chromium salts: potassium alum and chromium acetate within the specified limits is determined by the increase in the rheological parameters of the polysaccharide gel both at 20 ^o C and at elevated temperatures.

 To characterize the proposed crosslinker, gel samples were prepared using crosslinkers with different component contents, and solutions containing polysaccharide used solutions containing 0.36 wt.% Hydroxypropylguar (GPG) or carboxymethylhydroxypropyl guar (CMHPG) and 2 wt.% Potassium chloride, which usually injected into a fracturing fluid based on fresh water to reduce clay swelling.

 Example 1

 In 100 ml of fresh water, 2 g of potassium chloride was dissolved, and then 0.3 6 g of GPG was added to the resulting solution with stirring, after which stirring was continued for 20 minutes to completely hydrate the polysaccharide. 0.4 ml of a crosslinker, prepared as follows, was introduced into the obtained polysaccharide solution: 15 g of sodium tetraborate 10 g was gradually added to 35 g of glycerol while stirring, stirring was continued until a homogeneous mass was obtained, after which, without stopping mixing, 50 g of 5 were added to the resulting mixture % sodium hydroxide solution and stirring was continued until complete dissolution of sodium tetraborate tetraborate and a true crosslinker solution was obtained. Immediately after introducing the crosslinker into the polysaccharide solution, a crosslinked gel of high viscosity was obtained.

 Example 2

 A polysaccharide solution was prepared analogously to Example 1. 0.3 ml of a crosslinker prepared as follows was added to the obtained polysaccharide solution: gradually, to 40 g of glycerol was added and 17 g of sodium tetraborate tetraborate was added, stirring was continued until a homogeneous mass was obtained, after which stirring was continued , 43 g of a 15% potassium hydroxide solution were introduced into the resulting mixture, and stirring was continued until the ten-sodium sodium tetraborate was completely dissolved and a true crosslinker solution was obtained. Immediately after introducing the crosslinker into the polysaccharide solution, a crosslinked gel of high viscosity was obtained.

 Example 3

 A polysaccharide solution was prepared analogously to Example 1. 0.2 ml of a crosslinker prepared as follows was added to the obtained polysaccharide solution: 25 g of sodium ten-tetraborate was gradually added to 70 g of glycerol with stirring, stirring was continued until a homogeneous mass was obtained, after which, without stopping mixing, 5 g of a 40% sodium hydroxide solution were introduced into the resulting mixture, and stirring was continued until the ten-sodium sodium tetraborate was completely dissolved and a true crosslinker solution was obtained. Immediately after introducing the crosslinker into the polysaccharide solution, a crosslinked gel of high viscosity was obtained.

 Example 4

 A polysaccharide solution was prepared analogously to Example 1. 0.4 ml of a crosslinker prepared as follows was added to the obtained polysaccharide solution: 15 g of sodium ten-tetraborate was gradually added to 35 g of glycerol while stirring, stirring was continued until a homogeneous mass was obtained, after which, without stopping mixing, 50 g of a 5% potassium hydroxide solution were introduced into the resulting mixture, and stirring was continued until the ten-sodium tetraborate sodium was completely dissolved and a true solution was obtained. Then, 0.1 g of potassium alum (1 g / kg of solution) was added to 100 g of the solution, and the resulting mixture was again mixed until a true crosslinker solution was obtained. Immediately after introducing the crosslinker into the polysaccharide solution, a crosslinked gel of high viscosity was obtained.

 Example 5

 A polysaccharide solution was prepared analogously to Example 1. 0.3 ml of a crosslinker prepared as follows was added to the obtained polysaccharide solution: 17 g of sodium ten-tetraborate was gradually added to 40 g of glycerol with stirring, stirring was continued until a homogeneous mass was obtained, after which, without stopping mixing, 43 g of a 15% sodium hydroxide solution were introduced into the resulting mixture, and stirring was continued until the ten-sodium tetraborate sodium was completely dissolved and a true solution was obtained. Then, 2.5 g of potassium alum (25 g / kg of solution) was added to 100 g of the solution, and the resulting mixture was again mixed until a true crosslinker solution was obtained. Immediately after introducing the crosslinker into the polysaccharide solution, a crosslinked gel of high viscosity was obtained.

 Example 6

 A polysaccharide solution was prepared analogously to Example 1. 0.2 ml of a crosslinker prepared as follows was added to the obtained polysaccharide solution: 25 g of sodium ten-tetraborate was gradually added to 70 g of glycerol with stirring, stirring was continued until a homogeneous mass was obtained, after which, without stopping mixing, 5 g of a 40% potassium hydroxide solution were added to the resulting mixture, and stirring was continued until the ten-sodium sodium tetraborate was completely dissolved and a true solution was obtained. Then, 5.0 g of potassium alum (50 g / kg of solution) was added to 100 g of the solution, and the resulting mixture was again mixed until a true crosslinker solution was obtained. Immediately after introducing the crosslinker into the polysaccharide solution, a crosslinked gel of high viscosity was obtained.

 Example 7

 A polysaccharide solution was prepared analogously to Example 1. 0.3 ml of a crosslinker prepared as follows was added to the obtained polysaccharide solution: 17 g of sodium ten-tetraborate was gradually added to 40 g of glycerol with stirring, stirring was continued until a homogeneous mass was obtained, after which, without stopping mixing, 43 g of a 15% potassium hydroxide solution were introduced into the resulting mixture, and stirring was continued until the ten-sodium sodium tetraborate was completely dissolved and a true solution was obtained. Then, 2.5 g of chromium acetate (25 g / kg of solution) was added to 100 g of the solution, and the resulting mixture was again mixed until a true crosslinker solution was obtained. Immediately after introducing the crosslinker into the polysaccharide solution, a crosslinked gel of high viscosity was obtained.

 Example 8

 A polysaccharide solution was prepared analogously to Example 1. 0.4 ml of a crosslinker prepared as follows was added to the obtained polysaccharide solution: 15 g of sodium ten-tetraborate was gradually added to 35 g of glycerol while stirring, stirring was continued until a homogeneous mass was obtained, after which, without stopping mixing, 50 g of a 5% potassium hydroxide solution were introduced into the resulting mixture, and stirring was continued until the ten-sodium tetraborate sodium was completely dissolved and a true solution was obtained. Then, 0.1 g of chromium acetate (1 g / kg of solution) was added to 100 g of the solution, and the resulting mixture was again mixed until a true crosslinker solution was obtained. Immediately after introducing the crosslinker into the polysaccharide solution, a crosslinked gel of high viscosity was obtained.

 Example 9

 A polysaccharide solution was prepared analogously to Example 1. 0.2 ml of a crosslinker prepared as follows was added to the obtained polysaccharide solution: 25 g of sodium ten-tetraborate was gradually added to 70 g of glycerol with stirring, stirring was continued until a homogeneous mass was obtained, after which, without stopping mixing, 5 g of a 40% sodium hydroxide solution were introduced into the resulting mixture, and stirring was continued until the ten-sodium sodium tetraborate was completely dissolved and a true solution was obtained. Then, 5.0 g of chromium acetate (50 g / kg of solution) was added to 100 g of the solution, and the resulting mixture was again mixed until a true crosslinker solution was obtained. Immediately after introducing the crosslinker into the polysaccharide solution, a crosslinked gel of high viscosity was obtained.

 Example 10

 2 g of potassium chloride were dissolved in 100 ml of fresh water, and then 0.36 g of CMHPG was added to the resulting solution with stirring, after which stirring was continued for 20 minutes to completely hydrate the polysaccharide. 0.3 ml of a crosslinker, prepared as follows, was introduced into the obtained polysaccharide solution: 17 g of sodium tetraborate 10 g was gradually added to 40 g of glycerol with stirring, stirring was continued until a homogeneous mass was obtained, after which, without stopping stirring, 43 g of 15 g were added to the resulting mixture % and a solution of sodium hydroxide and stirring was continued until complete dissolution of ten-sodium tetraborate and obtaining a true solution. Then, 2.5 g of potassium alum (25 g / kg of solution) was added to 100 g of the solution, and the resulting mixture was again mixed until a true crosslinker solution was obtained. Immediately after introducing the crosslinker into the polysaccharide solution, a crosslinked gel of high viscosity was obtained.

The dynamic viscosity of the obtained gels at a temperature of 26 ^o C (80 ^o F) was determined on a Rheotest-2 rotational viscometer 3 minutes after preparation at a shear rate of 85, 100 and 170 s ^-1 , the consistency coefficient is "k", "Pa- with ⁿ "and the coefficient of non-nyutovsky behavior" n "were determined by mathematical processing of the obtained rheological curves. The rheological parameters of the gels at a temperature of 90 ^o C (193-194 ^o F) when holding it for 16 and 263 minutes were determined at a shear rate of 40, 100 and 170 s ^-1 , and the coefficients "k" and "n" were also determined by mathematical processing of the obtained rheological curves.

The compositions of the gels obtained on the basis of aqueous solutions of polysaccharides and boron crosslinkers of various component compositions are shown in table 1. The results of studies of the compositions of the gels according to table 1 are shown in tables 2 and 3. Table 2 shows the rheological characteristics of the obtained gels at a temperature of 26 ^o C (80 ^o F), and in table 3 - at a temperature of 90 ^o C (193-194 ^o F). For comparison, tables 1, 2 and 3 show the characteristics of the gel according to the prototype (claims 11-12), the data is taken from US patent N 5145590 - tables 11-12.

 As can be seen from tables 1, 2 and 3, when using the proposed crosslinker, polysaccharide gels were obtained, not only not inferior in quality to the gel from the prototype, but also having sufficiently high coefficient "k" and lower coefficient values "at sufficiently high viscosity" n ", which indicates a stronger structure of the obtained gels, and the most structured gels with the lowest non-Newtonian behavior coefficients of the liquid" n "at high values of the consistency coefficients" k "were obtained For the additional introduction of chromium potassium alum or chromium acetate into the crosslinker, items 4-10 in tables 1, 2 and 3.

As is known, the most structured gels have the greatest thermal stability; so when holding for 263 minutes at a temperature of 90 ^o C the gel of the prototype almost 2 times reduces the coefficient of consistency, while the gels obtained using the proposed stapler, retain high values of the coefficients "k" and much lower than that of the prototype , the values of the coefficients are "n". It is also known that the most structured gels have the greatest sand-holding ability, as well as the least friction pressure loss in the pipes. Thus, the proposed stapler will produce high-quality hydraulic fracturing fluids.

Sources of information taken into account:
1) US patent N 4619776, E 21 B 43/26, 1986

 2) US Patent N 5145590, E 21 B 43/26, 1992, prototype.

Claims (2)

1. The composition for the preparation of the reagent for crosslinking aqueous solutions of polysaccharides, including ten-sodium tetraborate, an organic solvent and an aqueous alkali solution, characterized in that it contains glycerin as an organic solvent, and a 5 - 40% solution as an aqueous alkali solution sodium or potassium hydroxides, and in addition - potassium alum or chromium acetate in the following ratio of components, wt.%:
Sodium tetraborate ten - 25 - 25
Glycerin - 35 - 70
5 - 40% aqueous solution of sodium or potassium hydroxide - 5 - 50
potassium alum or chromium acetate 1 - 50 g per 1 kg of a solution of sodium tetraborate, glycerol and sodium or potassium hydroxide.  2. A method of preparing a reagent for crosslinking aqueous solutions of polysaccharides, including pre-mixing ten-sodium sodium tetraborate with an organic solvent, followed by the addition of an alkaline aqueous solution, characterized in that the ten-sodium sodium tetraborate is mixed with a solvent, glycerol, and an aqueous alkali solution is added - 5-40% - sodium hydroxide or potassium hydroxide solution, and then potassium alum or chromium acetate is additionally added to the resulting true solution.

Images