RU2665324C1 - Electroconductive concrete - Google Patents

Abstract

FIELD: construction.

SUBSTANCE: invention relates to the construction and electric power industry and, in particular, to the field of creating composite materials based on natural and technogenic raw materials to produce electrically conductive concrete, it has electrical conductivity and resistivity, enough to use the material as an electrically conductive structural and heating structural material, as well as the manufacture of elements of grounding devices and antistatic floors. Electrically conductive concrete includes portland cement, sand, water and a carbon-containing component, it also uses fly ash and hyperplasticizer, with the following component ratio, by weight %: Portland cement 10–14; sand 14–19; fly ash 13–18; carbonaceous component 11.8–15.8; hyperplasticizer 0.2; water 42. In this case, thermosite sand is used as sand, and carbonaceous slime of aluminum production is used as a carbon-containing component. In addition, all dry components are subjected to mechanochemical activation in a vario-planetary mill to a specific surface of 550 m²/kg.

EFFECT: optimization of regulation of structure formation and homogenization of a multicomponent system, as well as a reduction in the cost of final products, energy and resource intensity of production.

1 cl, 2 tbl

Description

 The invention relates to the construction and electric power industry and, in particular, to the field of creating composite materials based on natural and technogenic raw materials to produce conductive concrete having electrical conductivity and resistivity sufficient to use the material as an electrically conductive structural and heating structural material, and also the manufacture of elements of grounding devices and antistatic floors.

Known resistive composite material consisting of components: quick-hardening cement in a weight percentage of 34-56; coarse chamotte fraction with a particle size of 0.15-2.5 mm - in a weight percentage of 1-35; silica sand, fraction 0.2-2.5 mm - in a weight percentage of 1-34; colloidal graphite - in a weight percentage of 3-15; finely divided chamotte fraction with a particle size of 0.05 to 0.09 mm in a weight percentage of 0.1-15; electrocorundum, fraction 0.1-0.5 mm - in a weight percentage of 0.1 to 20; mineral fiber with a length of 3 to 10 mm in a weight percentage of 0 to 5 (see RF patent No. 2231845, IPC H01C7 / 00, 2004).

The disadvantages of this material include a complex formulation and the high price of most components.

Compositions of electrically conductive concrete are known, which include 1-20% Portland cement, 18-85% ash and water (see US6461424 B1, 2002).

The disadvantage of this material is the low compressive strength - 8.3 MPa.

The closest adopted for the prototype is electrically conductive concrete containing cement, sand, water and powdered graphite, in the following ratio, wt.%:

powdered graphite 15-35 cement 20-30 sand 25-45 water rest

(see RF patent No. 2291130, IPC C04B28 / 04; C04B111 / 94, 2007).

The disadvantages of electrically conductive concrete are low strength characteristics, the difficulty of regulating the structure formation and homogenization of multicomponent systems, the presence of a limited form of the final product, which narrows the range of applications of products and systems based on them.

The present invention solves the problem of increasing the raw material base for the production of electrically conductive concrete with a wide range of consumer properties.

The technical result that is achieved in solving the problem is expressed in the optimal regulation of the structure formation and homogenization of a multicomponent system both due to the use of carbon substances in the concrete mix and through joint grinding of the components, as well as reducing the cost of the final product due to the use of concrete man-made waste, which reduces the energy and resource intensity of production.

The problem is solved in that the electrically conductive concrete, including Portland cement, sand, water and a carbon-containing component, is characterized in that it additionally uses fly ash and hyperplasticizer, in the following ratio of components, wt.%: Portland cement 10-14; sand 14-19; fly ash 13-18; carbon component 11.8-15.8; hyperplasticizer 0.2; water 42.

In this case, thermosite sand is used as sand, and carbonaceous sludge from aluminum production is used as the carbon-containing component. In addition, all dry components are subjected to mechanochemical activation in a varioplanetary mill to a specific surface area of 550 m ² / kg.

A comparative analysis of the essential features of the proposed technical solution with the essential features of the prototype and analogues indicates its compliance with the criterion of "novelty."

In this case, the distinguishing features of the claims solve the following functional tasks.

A sign indicating that "additionally use fly ash" allows to achieve a reduction in the consumption of Portland cement by replacing it with an activated filler of technogenic origin.

A sign indicating that "additionally use hyperplasticizer", can improve the rheological characteristics of the concrete mixture.

A sign indicating that "... thermosite sand is used as sand, and carbonaceous sludge of aluminum production as a carbon-containing component ...", allows to reduce the cost of concrete production through the use of cheap production waste.

A sign indicating that "... all dry components are subjected to mechanical activation ...", allows you to enhance the reactivity of the activated substance without changing its composition or structure.

Signs indicating the mass ratio are aimed at optimizing the composition, aimed at achieving a technical result.

Electrically conductive concrete is prepared as follows.

Excessive moisture up to 0.5% is removed from carbon sludge during heat treatment. The remaining dry components are added (Table 1) and co-milled in a varioplanetary mill to a specific surface of 550 m ² / kg, which contributes to an increase in its reactivity and application efficiency due to mechanochemical activation. The resulting dry mixture was shut with water at a water-binding ratio of 0.42 (Table 2).

Table 1

Conductive Concrete Components

Name of components Appointment as a part of concrete mix Mass fraction,% Normative document Portland cement CEM I 42.5N astringent 10-14 GOST 31108-2003 Fly ash CHP, brown coal, basic (O) - containing calcium oxide more than 10% by weight structural regulation 13-18 GOST 25818-91 Thermosite sand aggregate 14-19 GOST 8736-2014 Aluminum Carbon Slurry conductive component 11.8-15.8 TU 1914-99-011-97 Polycarboxylate dry hyperplasticizer plasticizing chemical modifier 0.2 EN 934-2-2009 Water binder mixing 42 GOST 23732-2011

table 2

Compositions and properties of electrically conductive concrete

Thus, the proposed composition of conductive concrete has the following advantages compared with the known:

- increased strength characteristics by more than 2 times while increasing electrical conductivity up to 2 times compared with the prototype;

- the economic effect is achieved by reducing the consumption of Portland cement by replacing it with an activated filler of technogenic origin and the use of aluminum sulphide and carbonaceous sludge in the formulation.

Features of resistive materials determine the use of their modifications to create heating elements and structures of volumetric and film types used in electrical systems for heating in the field of public and industrial construction, housing and communal services, agriculture, energy, etc. The use of carbon-containing components will ensure the stability of electrical properties.

Claims (2)

1. Electrically conductive concrete obtained from a raw material mixture containing Portland cement, sand, water and a carbon-containing component, characterized in that thermositic sand is used as sand, and carbonaceous sludge of aluminum production is used as the carbon-containing component, in addition, ash is additionally used in it entrainment and hyperplasticizer, in the following ratio of components, wt. %: Portland cement 10-14; termite sand 14-19; fly ash 13-18; carbonaceous sludge from aluminum production 11.8-15.8; hyperplasticizer 0.2; water 42. 2. Electrically conductive concrete according to claim 1, characterized in that all dry components are subjected to mechanochemical activation in a varioplanetary mill to a specific surface area of 550 m ² / kg.