RU2527435C2 - Complex additive for concretes and mortars (versions) - Google Patents

Abstract

FIELD: chemistry.

SUBSTANCE: claimed invention relates to composition of additive to concretes and mortars and can be applied in production of concrete and reinforced concrete products and constructions with concreting in wide range of environment temperature. In accordance with the first version complex additive for concrete and mortars contains polyalcohols and sodium sulphate, with additional introduction into it of sodium thiosulfate and rhodanide. Claimed complex additive contains said components with the following ratio, (wt %): polyalcohols - 30-80; sodium sulphate - 10-20; mixture of sodium thiosulfate and rhodanide - 10-50. Sodium nitrite can be additionally introduced into complex additive. In accordance with the second version complex additive for concretes and mortars contains polyalcohols and sodium formiate. It additionally contains acyclic, mono- or polycyclic amines with length of hydrocarbon radical C₁-C₃. Complex additive contains said components with the following ratio (wt %): polyalcohols - 30-70; sodium formiate - 15-25; acyclic, mono- or polycyclic amines - 15-45. Sodium nitrite can be additionally introduced into composition of complex additive.

EFFECT: obtaining complex additive for concretes and mortars with lower temperature of crystallisation, which does not impair indices of preservation of mobility of plasticised concrete mixtures, providing stable acquirement of strength in the entire range of temperatures, including negative ones.

4 cl, 3 tbl

Description

`The group of inventions relates to the composition of the additive for concrete and mortar and may find application in the production of concrete and reinforced concrete products and structures for concreting in a wide range of ambient temperatures.

In various concrete technologies, the practice of using additives that accelerate the set of early concrete strength and reduce the time period before concrete reaches critical strength is widespread. Ideally, such additives should be compatible with any type of plasticizing agent (naphthalenesulfonates, lignosulfonates, polycarboxylates).

The closest analogs to the claimed group of inventions by technical nature, purpose and achieved result are the following complex additives.

The complex additive, which is the closest analogue to option 1 of the present invention, contains salts of sulfuric acid, polyethylene glycols, sodium nitrite, and / or sodium chloride, and / or sodium sulfate [RF Patent N 2123483]. This additive is well compatible with all plasticizing additives, however, it is characterized by a relatively high crystallization temperature and does not provide sufficient intensity of concrete hardening when applied at low temperatures, and can also cause a decrease in concrete strength.

Complex additive [RF Patent 2168478 "Complex additive for concrete and mortar", publ. 06/10/2001,], which is the closest analogue to option 2 of the present invention, includes hydrochloric acid salts and polyalcohols, while it additionally contains formic acid salts as a hardening accelerator. As salts of hydrochloric acid, calcium, sodium and potassium chlorides are used. Sodium formate and calcium formate are used as formic acid salts. As polyalcohols, pentaerythritol and glycerin are used.

The specified additive has sufficiently low crystallization (freezing) temperatures, however, it accelerates the setting of the concrete mix and, in the presence of calcium salts, is not compatible with sulfate-containing superplasticizers (naphthalenesulfonates, lignosulfonates).

The technical task of the proposed group of inventions is the creation of a complex admixture for concrete and mortar with a low crystallization temperature, compatible with all additives with a plasticizing effect and not affecting the performance of the mobility of plasticized concrete mixtures, providing a stable set of strength over the entire temperature range, including negative ones.

To solve the problem according to the first embodiment, the complex additive for concrete and mortar contains polyalcohols and sodium sulfate, while a mixture of thiocyanate and sodium thiosulfate is added to it.

The proposed complex additive contains these components in the following ratio, (wt.%):

polyalcohols - 30-80;

sodium sulfate - 10-20;

a mixture of thiocyanate and sodium thiosulfate - 10-50.

At the same time, sodium nitrite can be added to the complex additive.

To solve the problem according to the second option, a comprehensive additive for concrete and mortar contains polyalcohols and sodium formate. Moreover, it additionally contains acyclic, mono- or polycyclic amines with the length of the hydrocarbon radical C1-C3.

The complex additive contains these components in the following ratio, (wt.%):

polyalcohols - 30-70;

sodium formate - 15-25;

acyclic, mono- or polycyclic amines - 15-45.

At the same time, sodium nitrite can be added to the composition of the complex additive.

The combination of sodium sulfate with a mixture of thiocyanate and sodium thiosulfate leads to a synergistic effect that provides a stable set of strength over the entire temperature range, including negative ones. The combined effect of sodium formate and acyclic, mono- or polycyclic amines with the length of the hydrocarbon radical C ₁ -C ₃ leads to a similar effect.

In this case, polyalcohols provide the effect of co-plasticization, increasing the mobility and lowering the crystallization temperature of the solution of the complex additive.

The third component of the additive — sodium nitrite in combination with salts of sulfuric acid and sodium formate — serves as a hardening accelerator and antifreeze additive, and the mutual combination of salts with each other significantly enhances the effect of the action of the individual components.

The inventive range of ratios of the components of complex additives according to options 1 and 2 is established experimentally and is optimal.

In the composition of the complex additive according to option 1, when the content of sodium sulfate is more than 20%, the period of maintaining the mobility of the concrete mixture is reduced, and when the content is less than 10%, the strength of concrete decreases at negative temperatures. When the content of polyalcohols is less than 30%, it is not possible to provide a stable antifreeze effect, and with the introduction of more than 80%, the strength characteristics of concrete deteriorate during hardening under normal conditions.

The introduction of less than 10% of a mixture of thiocyanate and sodium thiosulfate technologically does not lead to a significant improvement in providing a sustainable set of concrete strength over the entire temperature range, including negative ones. By increasing the content of the mixture of rhodanide and sodium thiosulfate above 50%, the period of maintaining the mobility of the concrete mixture is significantly reduced.

The sodium nitrite content can be up to 100% (in excess of 100%).

In the composition of the complex additive according to option 2, when the content of sodium formate is more than 25%, the freezing temperature of the solution of the complex additive is increased, and when the content is less than 15%, the set of strength at low temperatures worsens.

When the content of polyalcohols is less than 30%, it is not possible to provide a stable antifreeze effect, and with the introduction of more than 70% the strength characteristics of concrete deteriorate during hardening under normal conditions.

The introduction of acyclic, mono- or polycyclic amines of less than 15% does not lead to a synergistic effect from their combined use with sodium formate as part of a complex additive.

The sodium nitrite content can be up to 100% (in excess of 100%).

The technical essence of the invention and the achieved effects can be illustrated by the following examples.

For the preparation of complex additives of the prototype of option 1 use the mass. %: sodium sulfate - 80; polyethylene glycol - 10, sodium nitrite - 2, sodium chloride - 8.

To prepare a complex additive of the prototype of option 2, potassium chloride — 70, glycerol — 20, and calcium formate — 10 are used.

To prepare the complex additive according to the invention (option 1), sodium sulfate is used, while a mixture of rhodanide and sodium thiosulfate and polyalcohols is additionally introduced into it.

Example 1.1: polyethylene glycol - 30, sodium sulfate - 20, a mixture of rhodanide and sodium thiosulfate - 50.

Example 1.2: propylene glycol - 80, sodium sulfate - 10, a mixture of thiocyanate and sodium thiosulfate - 10.

Example 1.3: butanediol 60, sodium sulfate 20, a mixture of thiocyanate and sodium thiosulfate 20.

Example 1.4: sorbitol - 40, sodium sulfate - 15, a mixture of rhodanide and sodium thiosulfate - 45.

Example 1.5: glycerin - 70, sodium sulfate - 10, a mixture of rhodanide and sodium thiosulfate - 20, sodium nitrite - 10 (in excess of 100%).

Example 1.6: ethylene glycol - 35, sodium sulfate - 15, a mixture of thiocyanate and sodium thiosulfate - 50, sodium nitrite - 90 (in excess of 100%).

To prepare the complex additive according to the invention (option 2), polyalcohols, sodium formate are used, while it additionally contains acyclic, mono- or polycyclic amines with the length of the C ₁ -C ₃ hydrocarbon radical.

Example 2.1: ethylene glycol - 30, sodium formate - 25; triethylamine - 45.

Example 2.2: propylene glycol - 70, sodium formate - 15; morpholine - 15.

Example 2.3: glycerin 60; sodium formate 20; tetrazaadamantane - 20, sodium nitrite - 10 (in excess of 100%).

Example 2.4: ethylene glycol - 50; sodium formate - 25; diethanolamine - 25, sodium nitrite - 40 (in excess of 100%).

The above examples do not exhaust all possible variants of a complex additive, but help to more clearly demonstrate its properties.

The freezing study of complex prototype additives according to options 1 and 2 and complex additives according to the invention var. 1 and 2 are presented in table 1.

Table 1 №№ The composition of the complex additives Freezing temperature ° С one Prototype option 1 -5 2 Prototype option 2 -twenty 3 According to the invention, option 1 (example 1.1) -13 four According to the invention, option 1 (example 1.2) -fifteen 5 According to the invention, option 1 (example 1.3) -13 6 According to the invention, option 1 (example 1.4) -13 7 According to the invention, option 1 (example 1.5) -16 8 According to the invention, option 1 (example 1.6) -eighteen 9 According to the invention, option 2 (example 2.1) -23 10 According to the invention, option 2 (example 2.2) -25 eleven According to the invention, option 2 (example 2.3) -26 12 According to the invention, option 2 (example 2.4) -27

To assess the impact of the use of complex additives for concrete and mortar on the properties of concrete mix and concrete, in comparison with prototypes, tests were carried out in accordance with GOST 30459-2008 on a concrete mixture of the composition (kg / m ³ ): cement - 380, sand - 850, crushed stone - 990. The additive was dosed by dry matter as a percentage of the mass of cement. Compressive strength was determined according to GOST 10180.

The test results are given in table.2, 3.

Analysis of the results of the tests showed the following.

When comparing the strength characteristics of concrete with the prototype additives and additives according to the invention (Table 2), it can be seen that the use of the additive according to the invention allows for higher strength characteristics of concrete hardening at low temperatures. So, for the application variant of the additive according to the invention (option 1) at -15 ° С, the compressive strength of concrete at the age of 28 days is up to 11.9 MPa, which is up to 35% of the control sample and above the corresponding value for the application variant of the additive- prototype up to 15%. In addition, the complex additive according to the invention (var. 1), unlike the prototype, can be stored in winter conditions in unheated rooms. For option 2 of the complex additive according to the invention at -25 ° C, the compressive strength of concrete at the age of 28 days is up to 12.5 MPa, which is up to 36.8% of the control sample and higher than the corresponding value for the application of the additive prototype by 15% . It is important to note that such an increase is achieved precisely due to the additive effect, and not due to the B / C ratio. The use of complex additives according to the invention (var. 1 and 2) in comparison with the prototype additives when introduced in the same dosage of 1%, can significantly increase the period of preservation of the mobility of the concrete mixture.

For option 1, after thirty minutes, the precipitation of the cone of the concrete mixture with the complex additive according to the invention is 16-19 cm, and with the corresponding additive prototype 15 cm. Moreover, the use of the additive according to the invention allows for higher strength characteristics of ready-mixed concrete as in the early stages, so in adulthood. So for the application option of the additive according to the invention (option 1), the compressive strength of concrete at the age of 1 day is up to 13.9 MPa, which is 18% higher than the corresponding value for the application option of the prototype additive. In the future, the difference in strength characteristics decreases, but even at the age of 28 days it amounts to 11%.

For option 2, after thirty minutes, the sediment of the concrete cone with the complex additive according to the invention is 18-19 cm, and with the corresponding prototype additive - 13 cm, after 1 hour - 14-16 cm and 6 cm, respectively. Since the prototype additive according to option 2 contains calcium chloride, the increase in the strength of concrete with the additive according to the invention is not so pronounced. However, the use of the additive according to the invention is possible in any products, including reinforced ones, while a prototype containing corrosion-hazardous components can be used only in unreinforced products.

Thus, the proposed complex additive for concrete and mortar according to the invention (option 1) has a low crystallization temperature, is compatible with all additives with a plasticizing effect and does not impair the mobility retention properties of plasticized concrete mixtures, provides a stable set of strength over the entire temperature range, including negative ones.

The complex additive for concrete and mortar according to the invention (option 2) has a low crystallization temperature, is compatible with all additives with a plasticizing effect and does not impair the mobility retention characteristics of plasticized concrete mixtures, provides a stable set of strength over the entire temperature range, including negative ones.

table 2 Comparison of the effectiveness of complex additives prototypes and according to the invention No. The composition of the additive, wt.% Dosage,% (by commodity) W / C Ok see Hardening conditions Compressive strength, MPa % of control 7 days 28 days one control composition without additives - 0.55 13 Well. 28,2 34.0 2 prototype option 1 9.1 0.48 13 Well. 37.6 39.8 -15 ° C - 10.3 30.3 3 according to the invention, example 1.1 3.2 0.45 fourteen Well. 38.1 40.3 -15 ° C - 11.9 35.0 four according to the invention, example 1.2 3.2 0.45 Well. 37.9 40.1 -15 ° C - 11.5 33.8 5 according to the invention, example 1.3 3.2 0.45 Well. 38,0 40,2 -15 ° C - 11.0 32,4 6 according to the invention, example 1.4 3.2 0.46 Well. 38,2 40.5 -15 ° C - 10.7 31.5 7 according to the invention, example 1.5 3,5 0.45 Well. 37.9 40.1 -15 ° C - 11.7 34,4 8 according to the invention, example 1.6 4.0 0.44 Well. 38.3 40.5 -15 ° C - 12,2 35.9 9 prototype option 2 5,6 0.42 fifteen Well. 37.0 41.2 -25 ° C - 10.6 31,2 10 according to the invention, example 2.1 2.0 0.43 13 Well. 39.6 44.5 -25 ° C - 12.0 35.3 eleven according to the invention, example 2.2 2.0 0.43 13 Well. 39.1 44,2 -25 ° C - 12,2 35.6 12 according to the invention, example 2.3 2.2 0.43 13 Well. 39.3 44.0 -25 ° C - 12.5 36.8 13 according to the invention, example 2.4 3.0 0.42 fifteen Well. 39,4 44.8 -25 ° C - 12.5 36.8

Claims (4)

1. A comprehensive additive for concrete and mortar containing polyalcohols and sodium sulfate, characterized in that it is additionally introduced a mixture of thiocyanate and sodium thiosulfate in the following content of these components (wt.%):
polyalcohols - 30-80;
sodium sulfate - 10-20;
a mixture of thiocyanate and sodium thiosulfate - 10-50. 2. The complex additive for concrete and mortar according to claim 1, characterized in that it additionally contains sodium nitrite. 3. A complex additive for concrete and mortar containing polyalcohols and sodium formate, characterized in that it additionally contains acyclic, mono - or polycyclic amines with the length of the hydrocarbon radical C1-C3 in the following ratio (wt.%):
polyalcohols - 30-70;
sodium formate - 15-25;
acyclic, mono- or polycyclic amines - 15-45. 4. The complex additive for concrete and mortar according to claim 3, characterized in that sodium nitrite is additionally added to it.