RU2215712C1 - Blend for manufacturing light-weight high-strength ceramic propping members - Google Patents

Abstract

FIELD: ceramics. SUBSTANCE: objective of invention resides in manufacturing light-weight high-strength ceramic granules employed when performing hydraulic fracturing of rocks as propping members. Initial blend is prepared from aluminosilicate raw material, in particular kaolin thermally treated at temperature allowing minimum moisture absorption in material. Composition of blend is characterized by specific surface area above 19500 sq.cm/g, 0063 sieve residue less than 5% with weight percentage of particles below 2 mcm 5-60%, below 5 mcm 30-80%, below 10 mcm 50-90%, below 20 mcm 65-97%, and below 50 mcm 83-100%. EFFECT: increased strength al low cost of starting materials. 3 dwg, 3 tbl

Description

 The present invention relates to the ceramic industry and can be used to obtain lightweight high-strength ceramic granules of spherical shape - proppants used in hydraulic fracturing of rocks as a proppant.

 Due to the fact that the main task of proppants is to prevent the closure of cracks obtained during hydraulic fracturing, they must have a set of operational properties, the main of which is sufficient crushing strength.

Known lightweight proppant according to US patent 5188175 from kaolin with an alumina content (Al ₂ O ₃ ) in the range of 25-40 wt.%.

 The disadvantage of this mixture is the low content of aluminum oxide, which does not allow to obtain a high strength product.

 Known high-strength proppant according to US patent 5120455 from raw materials with an aluminum oxide content of 40-60 wt.%.

 The disadvantage of this mixture is that such an alumina content cannot be achieved using widespread refractory and kaolin clays without special additives (bauxite, alumina), which significantly increases the cost of the material and creates additional technological difficulties.

Closest to this invention (prototype) is the patent of the Russian Federation 2140875, in which for the production of granules using aluminum-silicon mixture containing alumina-containing raw materials with an additive that increases the strength of the granules. As alumina-containing raw materials take kaolin burnt at 700-900 ^o C containing 30-45 wt.% Al ₂ O ₃ , and as an additive, the following substances or mixtures thereof: alumina dust, baddeleyite, zirconium concentrate, burnt and not burnt bauxite at various ratios of components. The mixture is crushed to an average particle size of 3-5 microns.

The main disadvantage of this charge is that it requires the presence of such expensive components as zirconium-containing mineral baddeleyite with a high content of ZrO ₂ 91.0-96.0 wt.% (Up to 5.0 wt.% In the charge), powdered zirconium concentrate with the content of ZrO ₂ 60.0-65.0 wt.% (up to 10.0 wt.% in the charge), bauxite calcined at 800-1100 ^o With (up to 30 wt.% in the charge). The recipes of the mixture include several components, which creates additional difficulties in the process of preparing the mixture (dosing, mixing), in addition, it is necessary to adjust the ratio of these components when adding technological return to the mixture. These additives lead to a heavier weight of the obtained granules, which may not allow their use in the lightweight class.

 Another disadvantage of this material is its very fine grinding (up to an average particle size of 3-5 microns), which requires the use of expensive high-energy equipment.

 The problem to which the invention is directed, is to simplify the aluminum-silicon mixture for the production of proppants to contain only one relatively cheap material in it without any additives and reduce the requirement for the dispersed composition of the raw material.

The problem is solved in that the mixture for producing lightweight high-strength ceramic proppants from heat-treated crushed aluminosilicate raw materials according to the invention contains kaolin of the following chemical composition (wt.%, Per calcined substance) as Aluminosilicate raw materials: Al ₂ O ₃ 40.00-44, 00; SiO ₂ 54.00-56.00; Fe ₂ O ₃ 0.48-0.87; TiO ₂ 0.23-0.46; CaO 0.15-0.47; K ₂ O 0.45-0.91; Na ₂ O 0.10-0.33, heat-treated at a temperature that ensures minimal moisture absorption of the material, and having a dispersed composition with a specific surface area of more than 19500 cm ² / g, a residue on sieve 0063 of less than 5% with a mass fraction of particles of less than 2 microns 5-60%, less than 5 microns 30-80%, less than 10 microns - 50-90%, less than 20 microns 65-97%, less than 50 microns 83-100%.

In the future, the invention is illustrated by specific examples of its implementation and the accompanying drawings, in which:
figure 1 depicts the dispersed composition of the mixture;
FIG. 2 - curves reflecting the influence of the temperature of heat treatment of kaolin on moisture absorption in one day, depending on the chemical and dispersed compositions;
FIG. 3 - curves reflecting the influence of the temperature of heat treatment of kaolin on moisture absorption for 14 days, depending on the chemical and dispersed compositions.

For the manufacture of proppants, a one-component charge is proposed, consisting of heat treated at a temperature that provides minimal moisture absorption, kaolin with the most optimal ratio of basic chemical compounds, namely (wt.%, Per calcined substance): Al ₂ O ₃ 40.00-44.00 ; SiO ₂ 54.00-56.00; Fe ₂ O ₃ 0.48-0.87; TiO ₂ 0.23-0.46; CaO 0.15-0.47; K ₂ O 0.45-0.91; Na ₂ O 0.10-0.33, while kaolin has a dispersed composition with a specific surface area of more than 19500 cm ² / g, a residue on a 0063 sieve of less than 5% with a mass fraction of particles of less than 2 microns - 5-60%, less than 5 microns - 30-80%, less than 10 microns - 50-90%, less than 20 microns - 65-97%, less than 50 microns - 83-100%.

 The dispersed composition of the charge was determined in accordance with GOST 23905-79 "Non-metallic finely dispersed materials. Method for determining the dispersed composition".

 The specific surface was determined by the method of breathability of the material (the time it took for a certain volume of air to pass through the layer of the pressed material).

 The value of the specific surface, in contrast to bulk density, more fully characterizes the dispersed composition of the material in the entire range of particle sizes and especially the ability of the material of this dispersion to obtain a dense packing of particles.

 The use of kaolin with the specified chemical composition has the following advantages. This ratio is optimal for economic reasons - it allows the use of most domestic kaolin deposits with relatively cheap raw materials.

But, as you know, proppants from pure kaolin with a content of Al ₂ O ₃ up to 45 wt. % (on calcined substance) do not have high strength without additional reinforcing additives. For example, additives in the form of bauxite, alumina, baddeleyite, zirconium concentrate, etc. increase the content of mullite in the finished product and form a stronger crystal lattice.

In order to increase the low strength values of proppants made from pure kaolin, the following is proposed. As you know, almost all manufacturers of proppants produce kaolin in the temperature range of 600-900 ^o C, since above these temperatures the primary crystallization of mullite begins and, accordingly, a significant decrease in the surface energy of the powder material, which complicates the granulation process and the production of granules without pores. And porosity directly affects one of the main characteristics of the product - the strength of proppants (crush resistance). Therefore, obtaining a dense granule is one of the most important tasks.

The pores in the granules are formed as a result of the formation of granules in the granulator mixers and are explained by the following reasons. The main mineral constituting kaolin clays is kaolinite-hydroaluminosilicate Al ₂ O ₃ 2SiO ₂ 2H ₂ O. In kaolinite, part of the valencies of aluminum is bonded to silicon atoms through oxygen atoms, and part of the valencies to hydroxyls, and the position of hydroxyl groups in the structure of kaolinite is not the same: part of the hydroxyls is located on the surface of the package, and part is on the inner surfaces of the hydrarthillite layer. During the heating of kaolinite, part of the hydroxyls, forming a water molecule, evaporates to 600-700 ^o С, while the other part, which has more strong bonds with kaolinite cations, remains up to 1100 ^o С, and only with a sufficiently long heating leave their positions with the formation of water molecules .

 The residual amount of hydroxyl groups in dehydrated kaolin increases moisture absorption, since each hydroxyl group is able to attach three water molecules to itself. Rehydration occurs - the process of re-saturation of metakaolin crystals with hydroxyl groups, and at a deep, molecular level. Re-saturation of crystalline hydrates with water during further drying and firing and leads to the appearance of internal pores.

 The technological process for the formation of proppant granules in world practice is constructed in such a way that, regardless of how the granules are formed - in a spray drying apparatus or in a granulator-mixer - the mixture is mixed everywhere with water to a moisture content of 16-26%. Therefore, the ability of a material to absorb water at the capillary (intercrystalline) level, when water quickly leaves during drying and does not lead to the appearance of internal pores, rather than at the molecular level, is one of the main conditions for producing granules without pores.

 In this regard, the heat treatment of the mixture is carried out in modes that ensure its minimum moisture absorption. In this case, the bulk of the moisture absorbed by kaolin is free (capillary or intercrystalline) and easily evaporates during drying, without creating internal defects.

 The optimal modes of heat treatment of the material are selected based on the values of the minimum moisture absorption of the material. The method of measuring moisture absorption is the determination of losses during calcination after exposure to ground heat-treated kaolin for one or, for greater accuracy, 14 days at 100% humidity.

The influence of the temperature of the heat treatment in the temperature range 100-1300 ^o With kaolins of various chemical and dispersed compositions on moisture absorption is shown in table 1 (tables 1-3 see at the end of the description), and figure 2, 3 (for example, kaolins KZh- 3 TU 5729-078-00284530-98 and KZhB-83 TU 5729-080-00284530-98 quarry "Crane Log", Plast, Chelyabinsk region).

 In FIG. Figures 2 and 3 show curves reflecting the influence of the temperature of heat treatment of kaolin on moisture absorption for one day and for 14 days, respectively, depending on the chemical and dispersed compositions.

curve 1 - for kaolin "KZh-3", coarse grinding;
curve 2 - for kaolin "KZHB-83", coarse grinding;
curve 3 - for kaolin "KZh-3", fine grinding;
curve 4 - for kaolin "KZHB-83", fine grinding.

An analysis of the results shows that metakaolinite completely loses hydroxyl groups in the temperature range 1050-1100 ^o C. The moisture absorption of the material both in one day and in 14 days decreases with increasing temperature from 850 to 1050 ^o С, and with a further increase to 1150 ^o C rises again.

 With an increase in the content of finer fractions in the charge, moisture absorption increases, which is explained by an increase in the specific surface of the material and, as a consequence, an increase in the amount of adsorption moisture.

 In connection with the influence of the chemical and dispersed compositions of the raw materials used, in each specific case (for each brand of kaolin, each technological grinding regime), the optimal heat treatment conditions of kaolin to obtain minimal moisture absorption must be determined anew and the dependences of Fig. 2 or 3 must be built. But in any case the minimum moisture absorption value corresponds to the optimum heat treatment temperature for each specific condition.

Heat treatment of kaolin at temperatures above 1100-1150 ^o With undesirable, because aggregation (sintering) of metakaolin particles occurs, moisture absorption increases, and its abrasiveness significantly increases.

The influence of the moisture absorption values of heat-treated kaolin on the properties of the proppants obtained from it is shown in Table 2 (kaolin grade KZh-3, the specific surface of the charge is not less than 20 350 cm ² / g, the residue on sieve 0063 is less than 1.5%; the mass fraction of particles is less than 2 microns - 23%, less than 5 microns - 47%, less than 10 microns - 62%, less than 20 microns - 74%, less than 50 microns - 87%.

 The next important condition affecting the production of high quality proppants is the dispersed composition of the charge used, not only the absolute size of the grain size, but also the nature of its distribution is important.

 As can be seen from table 3, coarse grinding does not provide the required strength of the granules. This is due, first of all, to the presence of a large number of large granules larger than 63 microns in size with the presence of internal defects in the form of porosity and low-temperature weak meshes. Does not provide the required characteristics of the finished product and the absence of a fine fraction with a satisfactory content of a large fraction.

 At the same time, obtaining fine grinding (with a particle size of less than 10 microns) due to the ability of the material to agglomerate is associated with certain technological difficulties and significantly increases the cost of the charge.

The proppant from the proposed mixture is obtained as follows:
1. Take aluminosilicate raw materials, such as dry enrichment kaolin, grade KZh-3 TU 5729-078-00284530-98 of the Zhuravliniy Log deposit, Plast, Chelyabinsk Region.

 2. The material is pelletized, and loose pellets with a size of 0.2-15.0 mm and a moisture content of about 12-20% are obtained.

3. Produce heat treatment of the pellets at a temperature of minimal moisture absorption (from 1050 to 1100 ^o With depending on the dispersed composition).

4. After heat treatment, the pellets are milled in a mill until the dispersion of particles with a residue on sieve 0063 of less than 5%, a specific surface area of more than 19500 cm ² / g

 5. Produce granulation of the material in the mixer-granulator "EIRICH" (Germany).

 6. The granules are dried to a relative humidity of 2-3% and preliminary screening is carried out, returning substandard fractions with sizes greater than 2.0 mm and less than 0.4 mm back to the grinding.

7. Produce the final firing of granules at a temperature of 1350-1450 ^o C in a rotary gas furnace.

 8. The granules are cooled and dispersed into commercial fractions. The proppants obtained from the proposed charge meet all the requirements of GOST R 51761-2001 for "ALUMINO-SILICATE PROPANTS" and API RP60 "Methodological recommendations for testing high-strength proppants for hydraulic fracturing".

Claims (1)

The mixture for producing lightweight high-strength ceramic proppants from heat-treated crushed aluminosilicate raw materials, characterized in that as aluminosilicate raw materials contains kaolin of the following chemical composition, wt. %, on the calcined substance:
Al ₂ O ₃ - 40.00-44.00
SiO ₂ - 54.00-56.00
Fe ₂ O ₃ - 0.48-0.87
TiO ₂ - 0.23-0.46
CaO - 0.15-0.47
K ₂ O - 0.45-0.91
Na ₂ O - 0.10-0.33
heat-treated at a temperature that ensures minimal moisture absorption of the material, and having a dispersed composition with a specific surface area of more than 19500 cm ² / g, a sieve residue of 0063 of less than 5% with a mass fraction of particles of less than 2 microns 5-60%, less than 5 microns 30-80 %, less than 10 microns 50-90%, less than 20 microns 65-97%, less than 50 microns 83-100%.

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