RU2821877C1 - Gypsum-cement-pozzolanic construction mixture for 3d printing - Google Patents

Abstract

FIELD: construction materials.

SUBSTANCE: invention relates to the industry of construction materials and can be used for production of construction products and structures in technology of additive production by method of layer-by-layer extrusion (3D printing) of crude mixture based on portland cement, hemihydrate gypsum, sand, finely ground pozzolanic component, superplasticizer, setting and hardening time regulator, sodium methylsilanthriol and water. Gypsum-cement-puzzolanic construction crude mixture for 3D printing includes portland cement, sand, superplasticiser based on sodium salts of polymethylene naphthalene sulphonic acids "Polyplast SP-1", water, finely ground pozzolanic component of metakaolin with hydraulic activity of not less than 1,200 mg/g, degree of grinding not less than 2,000 m²/kg. Portland cement is used containing the following, wt.%: tricalcium silicate 63.0, tricalcium aluminate 6.1, sand used is quartz sand with fineness modulus of 3 and moisture content of 1–3%, and additionally it contains hemihydrate gypsum, regulator of setting and hardening time "БЕСТ-ТБ" and sodium methylsilanetriol "ГКЖ-11 Н" at a certain content of components.

EFFECT: reduced consumption of portland cement, increased stability of shape, resistance to penetration, ultimate bending strength of hardened composites printed on 3D printer, reduced average density of composites while ensuring their water resistance.

1 cl, 2 tbl

Description

The invention relates to the field of building materials industry and can be used for the manufacture of building products and structures in additive manufacturing technology using layer-by-layer extrusion (3D printing) of a raw mixture based on Portland cement, semi-hydrous gypsum, sand, finely ground pozzolanic component, superplasticizer, setting time regulator and hardening, sodium methylsilanetriol and water.

A known raw material mixture based on cement for construction 3D printing, including sulfoaluminate cement - 150-400 kg, ash - 0-250 kg, sand with a particle diameter of 0.075-5 mm, polypropylene fiber with a length of 3-6 mm, superplasticizer PCE produced by Shandong Hongyi Technology Co., Ltd – 1.5-2.5% by weight of cement, retarder sodium tetraborate and tartaric acid in a ratio of 1:(1-1.5) – 0.01-0.2% by weight of cement, in this case, the 10-minute slump of the proposed cement-based material is 90-110 mm, the beginning of setting is 15-80 minutes, the end of setting is 30-100 minutes [1]. The disadvantages of this invention are the presence of a large number of mixture components, increased consumption of mixture components and an increase in its cost caused by the use of fast-hardening sulfoaluminate cement and a retarder.

A highly thixotropic raw material mixture for construction 3D printing is known, including, wt.%: special thixotropic agent 1.0-3.0, cement 35-40, superplasticizer based on polycarboxylate esters 0.1-0.4, polypropylene fiber 0 ,1-0.4, water 12.5-14.5, sand – the rest [2]. The disadvantages of this invention are a decrease in the physical and mechanical characteristics of the composite at temperatures above 140 ⁰ C, caused by the melting of polypropylene fiber; increased consumption of Portland cement, leading to increased costs.

A modified polymer cement composite material for 3D printing is known, including, wt.%: Portland cement 24.37-34.16, polyvinyl acetate dispersion 2.44-2.56, sand 50.74-61.38, liquid glass 1.70- 2.44, polypropylene fiber 0.02-0.03, phloroglucinfurfural modifier 0.05-0.07, water – the rest [3]. The disadvantages of this invention are the short start time of setting - up to 45-70 minutes, which makes it difficult to transport the raw material mixture from the plant to the construction site, low compressive and bending strength at the age of 28 days.

A known gypsum-cement-pozzolanic composition, including, by weight. %: Portland cement 53.5-53.8, semi-hydrous gypsum 14.0-14.14, pozzolanic additive - metakaolin 1.3-1.44, modifying additive 2.6-3.0, containing, wt. %: carboxylate polyester “Ethacryl™ HF” – 76.7-77.1, setting and hardening time regulator “Best-TB” – 17.7-18.1, polymethylhydrosiloxane – 5-5.4; water (rest) [4]. The disadvantages of this invention are the high cost, increased consumption of Portland cement caused by the lack of filler in the composition, the unsuitability of this composition for additive manufacturing technology using layer-by-layer extrusion (3D printing) due to its self-compacting ability, leading to a lack of dimensional stability, and the presence of accelerated start and end times of setting – 18-23 minutes, causing a reduction in the viability of the mixture.

A two-phase mixture based on cement is known for composites in construction 3D printing technology, phase 1 of which contains components in the following mass ratio of the solid phase,%: Portland cement 44.1-44.5, sand 55.14-55.4, xanthan gum 0 .08-0.1, technical tetrapotassium pyrophosphate 0.08-0.1, polypropylene fiber 0.2-0.3; phase 2 contains components in the following mass ratio of the liquid phase,%: superplasticizer 4.1-4.6, water 95.4-95.9 [5]. The disadvantages of this invention are the increased consumption of Portland cement and superplasticizer (1.2-1.4% by weight of Portland cement), low dimensional stability of printed layers from the raw material mixture, high shrinkage deformations of the hardened composite due to increased consumption of Portland cement and the use of sand belonging to the “very fine” group "(according to GOST 8736-2014), low flexural strength of the hardened composite, a decrease in the physical and mechanical characteristics of the composite at temperatures above 140 ° C caused by the melting of polypropylene fiber, the use of tetrapotassium pyrophossphate and xanthan gum not intended for use as viscosity modifiers as additives for concrete and mortars (according to GOST 24211-2008). Another disadvantage of the invention is the lack of data on the moisture content of the components of the raw mixture, which affects the rheological and physical-mechanical properties of the composites, as well as the lack of data on the implementation of this invention on a 3D printer that implements the layer-by-layer extrusion method and the quality of the resulting products. In addition, the disadvantage is the method of sample preparation used in the invention, which consists in their production in molds of 70x70x70 mm, 70x70x280 mm, while the construction 3D printing technology eliminates the use of molds, which leads to a change in the pore structure of the composite and distortion of reliable results physical and mechanical properties (compressive and tensile strength, density, water absorption, etc.).

The closest solution to the proposed invention is a raw material mixture for additive construction production, including, by weight. %: Portland cement - 21.0-24.0, quartz sand with a particle size modulus of 2.2-2.4 and a moisture content of 1-2% - 61.44-64.93, finely ground pozzolanic component - metakaolin with a hydraulic activity of at least 1200 mg/g, grinding degree of at least 2000 m ² /kg - 2.1-2.4, superplasticizer based on polycarboxylate ethers "MasterGlenium 430" - 0.21-0.24, polysiloxane ether "MasterPel 793" - 0.010-0.012 , water – 11,750-11,908 [6]. The disadvantages of this invention are the high cost caused by the increased consumption of Portland cement, the high average density of the composites, which leads to the weight of the molded structures, and the low dimensional stability of the printed layers from the raw material mixture.

The objective of the invention is to reduce the consumption of Portland cement, increase the dimensional stability, penetration resistance, and flexural strength of hardened composites printed on a 3D printer, reducing the average density of the composites while ensuring their water resistance.

The technical result of the proposed solution is a reduction in the consumption of Portland cement, an increase in dimensional stability, penetration resistance, and the flexural strength of hardened composites printed on a 3D printer, a decrease in the average density of the composites while ensuring their water resistance.

This task is achieved by the fact that a gypsum cement-pozzolanic construction raw material mixture for 3D printing, including Portland cement, sand, a superplasticizer based on sodium salts of polymethylene naphthalene sulfonic acids "Poliplast SP-1", water, a finely ground pozzolanic component - metakaolin with a hydraulic activity of at least 1200 mg/ g, grinding degree of at least 2000 m ² /kg, differs in that they use Portland cement containing, wt.%: tricalcium silicate 63.0, tricalcium aluminate 6.1, quartz sand with a fineness modulus of 3 and a moisture content of 1 is used as sand -3%, and additionally it contains semi-aqueous gypsum, setting and hardening time regulator - “BEST-TB” and sodium methylsilanetriol “GKZh-11 N” with the following component content, wt.%:

Specified Portland cement 5.59 Semi-aqueous gypsum 21.2 Specified sand 54.9-55.9 Superplasticizer "Poliplast SP-1" 0.07-0.08 Setting and hardening time regulator – “BEST-TB” 0.05 The specified finely ground pozzolanic component is metakaolin 1.12 Sodium methylsilanetriol "GKZh-11 N" 0.007-0.008 Water rest

To produce the raw mixture for additive construction production, the following materials were used:

Portland cement CEM I 42.5N produced by Sukholozhskcement LLC (GOST 31108-2020) with the following mineralogical composition: C ₃ S – 63.0%, C ₂ S – 14.6%, C ₃ A – 6.1%, C ₄ AF – 10.4%;

Semi-hydrous gypsum grade G6BII produced by Arakchinsky Gypsum LLC (GOST 125-2018);

Quartz sand from the Kamsko-Ustinsky deposit of the Republic of Tatarstan with a fineness module of 3, humidity 2.5% (GOST 8736-2014);

Superplasticizer based on sodium salts of polymethylene naphthalene sulfonic acids "Poliplast SP-1" produced by Poliplast Kazan LLC, which is a brown liquid without chlorides, density at 20°C 1.18 g/cm3, pH - 8;

Regulator of setting and hardening times – “BEST-TB”, produced by LLC “Innovative Technologies”. "BEST-TB" belongs to the superplasticizers of the first group and is a copolymer based on carboxylic acid esters with the addition of a dark brown phosphate component with a density (at 20 °C) of 1.24 g/cm ³ , dry matter mass fraction 20-30 %;

Finely ground pozzolanic component - metakaolin with a hydraulic activity of at least 1200 mg/g, degree of grinding of at least 2000 m ² /kg (TU 5729-098-12615988-2013). To prepare the samples, metakaolin was used with a hydraulic activity of 1232.7 mg/g and a degree of grinding of 2068 m ² /kg;

Sodium methylsilanetriol "GKZh-11N" produced by PJSC "Khimprom", which is a dark brown liquid with a density of 1.15 g/cm3 at 20°C;

Tap drinking water that meets the requirements of GOST 23732-2011.

The proposed invention is carried out as follows: pre-dosed dry components of the raw material mixture are loaded into a working mixer, forming a gypsum-cement-pozzolanic binder - Portland cement, semi-hydrous gypsum, metakaolin and mixed until a homogeneous mass is obtained. Then pre-dosed quartz sand is loaded into the operating mixer and mixed until a homogeneous mass is obtained. Then dosage by weight of water, superplasticizer "Poliplast SP-1", setting and hardening time regulator - "BEST-TB", sodium methylsilanetriol "GKZh-11 N", mix them until a homogeneous solution is obtained and gradually add it to the thoroughly mixed dry components, mixing the mixture until a homogeneous mass is obtained with mobility Pk 2 (according to GOST 28013-98) with a reference cone immersion depth of 7-8 cm. At the next stage, the 3D printer is prepared: the inner surface of the removable storage hopper is moistened with tap drinking water or release agent. Next, the removable storage hopper of the construction 3D printer is filled with the prepared raw material mixture and test extrusion is carried out until the resulting extrudate is homogeneous. Then the raw material mixture is formed by layer-by-layer extrusion (3D printing) on a construction 3D printer (for example, “AMT” S-6044 from SPETSAVIA LLC) in accordance with a previously prepared three-dimensional digital model. The three-dimensional digital model of the samples is a strip 40 cm long, with a single layer height of 20 mm. The raw material mixture is printed using the following adjustable printing parameters set in the “Mach3” software package (Artsoft founder Art Fenerty): spindle rotation speed is 3000-5000 units, feed speed – 4000-6000 units/min.

The shape stability of printed layers from the raw material mixture was assessed by the ability of the mixture to maintain its position in space under the influence of technological factors, namely, by the maximum height of the printed sample without technological interruptions until it reaches a critical state - loss of stability as a whole, characterized by its overturning or loss of stability of the sample shape with displacement printed layers.

The penetration resistance of the raw mixture was determined in accordance with the requirements of ASTM C403 “Standard Test Method for Time of Setting of Concrete Mixtures by Penetration Resistance” according to the resistance of the raw mixture to penetration of the plunger of a C194 pocket penetrometer with a cross-sectional diameter of 6.35 mm for 150 minutes after the start of its extrusion on a construction 3D printer.

The water resistance of hardened composites was assessed by the softening coefficient, which is equal to the ratio of the ultimate compressive strength of the material in a water-saturated state to the ultimate strength of the dry material. Samples are considered water-resistant when they reach a softening coefficient of 0.8 or higher.

Samples were also tested according to the prototype using Portland cement CEM I 42.5N in accordance with GOST 31108-2020, sand with a fineness modulus of 2.3 with a moisture content of 1.5% in accordance with GOST 8736-2014, superplasticizer based on polycarboxylate ethers "MasterGlenium 430", finely ground pozzolanic component – metakaolin, polysiloxane ether “MasterPel 793”, water.

After 28 days of normal hardening, samples were prepared for testing, molded by layer-by-layer extrusion (3D printing), by cutting them into prisms measuring 40x40x160 mm. The average density of the hardened composite was determined according to GOST 12730.1-2020 “Concrete. Methods for determining density". The flexural strength of the hardened composite was determined on beam samples with dimensions of 40x40x160 mm according to GOST 5802-86. “Construction mortars. Test methods" using the MII-100 testing machine.

The compositions of raw mixtures for additive construction production are given in Table 1, physical and mechanical properties for the compositions are given in Table 2.

Table 1

Components Compositions of raw material mixtures for additive construction production, wt. % 1 2 3 4 5 (prototype) Portland cement 5.2 5.59 5.59 6.5 22.5 Semi-aqueous gypsum 21.5 21.2 21.2 20.5 Sand 53.4 54.9 55.9 57.0 63.18 Superplasticizer "MasterGlenium 430" 0.23 Superplasticizer "Poliplast SP-1" 0.05 0.08 0.07 0.11 Setting and hardening time regulator "BEST-TB" 0.04 0.05 0.05 0.07 Metakaolin 1.0 1.12 1.12 1.5 2.25 Sodium methylsilanetriol "GKZh-11 N" 0.003 0.008 0.007 0.009 Polysiloxane ether "MasterPel 793" 0.011 Water 18,807 17,052 16,063 14,311 11,829

table 2

Properties Physical and mechanical properties for compositions 1 2 3 4 5 (prototype) Form stability of printed layers from the raw material mixture (height of the product obtained by 3D printing without technological interruptions), cm 12 21 21 7 20 Penetration resistance at 150 minutes of hardening, kPa 4100 3750 3640 2980 330 Average composite density, kg/ ^m3 1840 1890 1870 1900 2080 Ultimate bending strength at 28 days, MPa 6.2 7.5 7.3 7.0 6.5 Water resistance No Yes Yes Yes Yes

From the given data it follows that the maximum values of the dimensional stability of printed layers from the raw material mixture, the flexural strength of hardened composites, are achieved when the raw material mixture contains Portland cement - 5.59% of the total mass of the composition, semi-aqueous gypsum - 21.2%, sand – 54.9-55.9%, superplasticizer “Poliplast SP-1” – 0.07-0.08%, setting and hardening time regulator “BEST-TB” – 0.05%, finely ground pozzolanic component – metakaolin – 1 .12%, methylsilanetriolpotassium salt "GKZh-11 K" - 0.007-0.008%. When introducing Portland cement, sand, superplasticizer "MasterGlenium 115", setting and hardening time regulator "BEST-TB", finely ground pozzolanic component - metakaolin, sodium methylsilanetriol "GKZh-11 N", in quantities less than those indicated in table 1 (composition 1), There is a decrease in the dimensional stability of the printed layers from the raw material mixture, the flexural strength, an increase in the penetration resistance at 150 minutes of curing, the average density of the hardened composites, and their water resistance is not ensured. When they are introduced in quantities greater than those indicated in Table 1 (composition 4), the dimensional stability indicators of printed layers from the raw material mixture, penetration resistance at 150 minutes of curing, and bending strength are reduced, and the average density of compositions printed on a 3D printer increases.

The gypsum-cement-pozzolanic construction raw material mixture for 3D printing, obtained according to the present invention, has a reduced consumption of Portland cement, increased dimensional stability, penetration resistance at 150 minutes of curing, flexural strength of hardened composites printed on a 3D printer, low average density of composites while ensuring their water resistance.

The use of gypsum-cement-pozzolanic binder makes it possible to reduce the consumption of Portland cement in the raw mixture, the average density of composites printed on a 3D printer, and increase the penetration resistance by 150 minutes of curing.

The use of coarse sand with a fineness modulus of 3 in combination with a gypsum-cement-pozzolanic binder, a superplasticizer based on sodium salts of polymethylene naphthalene sulfonic acids "Poliplast SP-1", a setting and hardening time regulator - "BEST-TB" and sodium methylsilanetriol "GKZh-11 N" allows increasing the flexural strength of cured 3D printed composites while ensuring their water resistance.

The use of superplasticizer "Polyplast SP-1" based on sodium salts of polymethylene naphthalene sulfonic acids in an amount of 0.07-0.08 wt.%, quartz sand with a fineness modulus of 3 and a moisture content of 1-3% in an amount of 54.9-55.9 wt.% allows you to reduce the amount of mixing water, increase the physical and mechanical characteristics of the hardened composite while simultaneously ensuring increased dimensional stability of the raw mixture.

The introduction of a finely ground pozzolanic component - metakaolin with a degree of grinding of at least 2000 m ² / kg, hydraulic activity of at least 1200 mg / g can improve the formability of the raw mixture by ensuring cohesion, homogeneity and plasticity, reduce the concentration of calcium hydroxide in the system, thereby providing favorable conditions for the formation of stable structures during joint hydration and hardening of gypsum and cement binders.

The use of semi-aqueous gypsum in an amount of 21.2 wt.% leads to acceleration of the processes of structure formation of the mixed binder, thereby providing increased penetration resistance at 150 minutes of curing.

Thus, the proposed solution makes it possible to obtain a gypsum-cement-pozzolanic construction raw material mixture for 3D printing with reduced consumption of Portland cement, which has high dimensional stability, and products based on it with increased bending strength characteristics and low average density while ensuring their water resistance.

Information sources:

1. Patent CN 105753404A, B33Y70/00, Cement-based material used for building 3D (three-dimensional) printing, appl. 02/13/2016, publ. 07/13/2016.

2. Patent CN 108715531A, C04B28/02, A kind of high thixotropic 3D printing concrete and preparation method thereof, application. 06/12/2018, publ. 08/28/2020.

3. Patent, RU 2 661 970, С04В 28/04, C04В 14/02, С04В 22/08, С04В 26/00, С04В2111/20, С04В2111/343, Modified polymer cement composite material for 3D printing, Poluektova V.A. ., Shapovalov N.A., Chernikov R.O., Evtushenko E.I., patent holder Federal State Budgetary Educational Institution of Higher Education "Belgorod State Technological University"., application. 07/31/2017, publ. 07/23/2018, bulletin. No. 21.

4. Patent, RU 2 551 179, C04B 11/30, Gypsum-cement-pozzolanic composition, Izotov V.S., Mukhametrakhimov R.Kh., Karimov R.F., Galautdinov A.R., Tagirova Yu.V., patent holder Federal State Budgetary Educational Institution of Higher Professional Education "Kazan State University of Architecture and Civil Engineering", application. 02/14/2014, publ. 05/20/2015, bulletin. No. 14.

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Claims (2)

Gypsum cement-pozzolanic construction raw material mixture for 3D printing, including Portland cement, sand, superplasticizer, water, finely ground pozzolanic component metakaolin with a hydraulic activity of at least 1200 mg/g, grinding degree of at least 2000 m ² /kg, characterized in that Portland cement is used , containing, wt.%: tricalcium silicate 63.0, tricalcium aluminate 6.1, quartz sand with a fineness modulus of 3 and a moisture content of 1-3% is used as sand, a superplasticizer based on sodium salts of polymethylene naphthalene sulfonic acids “Poliplast SP-” is used as a superplasticizer 1" and additionally it contains semi-aqueous gypsum, setting and hardening time regulator "BEST-TB" and sodium methylsilanetriol "GKZh-11 N" with the following content of components, wt.%: Specified Portland cement 5.59 Semi-aqueous gypsum 21.2 Specified sand 54.9-55.9 Superplasticizer "Poliplast SP-1" 0.07-0.08 Setting and hardening time regulator "BEST-TB" 0.05 Specified finely ground pozzolanic component metakaolin 1.12 Sodium methylsilanetriol "GKZh-11 N" 0.007-0.008 Water rest