KR101418241B1 - Eco-friendly white tile adhesive composition and method of manufacturing the same - Google Patents

Abstract

The present invention relates to a composition of an environmentally friendly white tile adhesive based on blast furnace slag powder which is an industrial by-product for the purpose of energy reduction and CO ₂ reduction and more specifically to a method for producing mortar using blast furnace slag as a main binder, (Ca (OH) 2 content: 80 to 90%), which is composed of 2 to 10 kg of any one or more anhydrous gypsum selected from natural anhydrous gypsum (SO3 content 54 to 56%), flue gas desulfurization gypsum and chemical anhydrous gypsum, (50 to 60% of Ca (OH) 2 + 50 to 40% of CaSO4) obtained by digesting flue gas desulfurized gypsum lime, high purity lime (Ca (OH) 2 content 90 to 98% 0.2 to 1 kg of a methylcellulose thickener, 0.2 to 1.2 kg of a re-oiled powder EVA resin, 0.2 to 1.2 kg of a calcium formate curing accelerator 0.2 ~ 1.2 kg, including 150 ~ 180kg of silica sand The Eco white tile adhesive composition and to a method of manufacturing the same.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a white tile adhesive composition,

The present invention relates to a composition of an environmentally friendly white tile adhesive based on blast furnace slag, which is an industrial by-product, and a method for producing mortar for the purpose of energy reduction and CO ₂ reduction in a construction site.

Recently, there is an urgent need for alternative measures to solve global warming such as carbon dioxide, greenhouse gas emission restriction, and energy saving.

 The most widely used tile adhesives in the construction industry are floor and wall tiles, and the main binder is white cement. The white cement is an energy non-uniform material like ordinary cement, and it is a major carbon dioxide emission industry, with the steel industry producing about 0.9 tons of carbon dioxide to produce 1 ton of cement.

Recently, in order to reduce CO ₂ and to meet the various performance requirements of customers, research on the application of alkali stimulants to blast furnace slag has been actively carried out to replace cement using industrial byproducts. However, studies on the alkaline activation reaction of blast furnace slag have been performed by blending the blast furnace slag, which is an industrial by-product generated by each production site, or a mixture of two or more additional blending materials at a certain ratio, and most of the conventional technologies related to the alkali activating agent Is an expensive inorganic chemical substance which is dependent only on high alkali and is mainly composed of NaOH, KOH, NA ₂ SiO ₃ , NA ₂ SO ₄ etc. Among the alkali activators reported in the previous studies, Waterglass (sodium silicate) requires a duplicate construction procedure in which the additional alkali activator is quantitatively weighed, mixed, and poured in the actual field construction, and it can be put to practical use due to the use of expensive water glass Technology is not enough.

In Korean Patent Registration No. 1011556390000 (20120605), a raw material mixture obtained by mixing and kneading liquid sodium silicate, which is the main raw material, with zinc oxide, aluminum hydroxide, diatomaceous earth, active kaolin, titanium dioxide, and a subsidiary material comprising magnesia, And 30% by weight of liquid sodium silicate, 15-30% by weight of zinc oxide, aluminum hydroxide of aluminum hydroxide, and aluminum hydroxide are mixed with 100% by weight of the raw material mixture. 10 to 20% by weight of diatomaceous earth, 10 to 20% by weight of diatomaceous earth, 5 to 10% by weight of active kaolin, 2 to 5% by weight of titanium dioxide and 2 to 7% by weight of magnesia are mixed and milled and pulverized; The additive is prepared by mixing 5 to 10 wt% aqueous solution of hydrochloric acid, 10 to 30 wt% aqueous solution of citric acid and 10 to 30 wt% aqueous solution of aluminum dihydrogenphosphate at a weight ratio of 1: 5: 1 to 2: 1 to 5, ≪ / RTI > Which is prepared by adding 5 to 25 parts by weight of the additive to 100 parts by weight of the raw material mixture, mixing and pulverizing the mixture, and a manufacturing method thereof.

In the publication No. 1008330980000 (20080522), 20 to 80 parts by weight of sand, 2.0 to 30 parts by weight of a silicate-based inorganic adhesive, and 1.0 to 15 parts by weight of a water dispersible resin composition are mixed with 100 parts by weight of a ceramic mineral, The disclosed cement-free mortar composition is disclosed,

The publication No. 1007416370000 (20070714) discloses a method of producing a pre-mixed material by mixing A) 50 to 85% by weight of an aggregate and 15 to 50% by weight of a reactive powder; B) mixing the reactive agent with the reactive agent in an amount of 0.3 to 0.7 weight ratio of the reactive binder, 0.005 to 0.05 weight ratio of the high performance water reducing agent, and 0.2 to 1.0 weight ratio of the inorganic curing activator to the weight of the reactive binder, Thereby producing a mineral complex; C) molding the block using the mineral complex; D) natural curing at room temperature for 1 to 28 hours; E) 40 to 100 for 1 to 4 days, and discloses an environmentally friendly block without cement and a method for producing the same.

In Korean Patent Laid-Open Publication No. 1020120003133 (20120110), a raw material mixture prepared by mixing active sodium kaolin, sodium silicate, sodium carbonate, calcium carbonate, unsweetened talc, aluminum hydroxide, titanium dioxide, and magnesia, In order to improve the water resistance and adhesion strength, one of aqueous type modified SBR (styrene butadiene rubber) or additives such as modified acrylic resin or modified polyurethane resin or modified latex or modified EVA (Ethylene Vinyl Acetate) is selected and added Wherein the raw material mixture comprises 40 to 60 wt% of liquid sodium silicate, 15 to 25 wt% of active kaolin, 5 to 10 wt% of soda feldspar, 5 to 10% by weight of calcium, 5 to 10% by weight of talc, 5 to 10% by weight of aluminum hydroxide, 1 to 5% by weight of titanium dioxide, 1 to 5 of magnesia % Of the additive is mixed with a vertical mixer or a high-viscometric high-viscosity mixer. The mixture is then mixed with a high-viscosity mixer or a vertical mixer. And 0.3% by weight of the inorganic adhesive composition and mixing the same to improve the water resistance and the adhesive strength.

The publication No. 1020070056315 (20070604) discloses a ceramic fiber having a ratio of diameter to length after crushing of 1: 1 to 200, which is the same as the composition of ceramic paper, inorganic fibers, inorganic colloidal materials, It can be seen that an inorganic binder adhesive for a ceramic paper including a binder is disclosed.

1. Korean Registered Patent Publication No. 1011556390000 (20120605). 2. Korean Patent Registration No. 1008330980000 (20080522). 3. Korean Patent Registration No. 1007416370000 (20070714) 4. Korean Patent Laid-Open Publication No. 1020120003133 (20120110) 5. Domestic Published Patent Publication No. 1020070056315 (20070604)

Conventional back cement is produced in the same way as general cement production process when manufacturing tile adhesives used in construction of floor and wall tiles. Therefore, in the present invention, white cement is used as a by-product blast furnace slag fine powder in order to reduce energy and CO2. In the application of blast furnace slag, general lime (Ca (OH) 2 content 80 ~ 90% (50 to 60% of Ca (OH) 2 + 50 to 40% of CaSO4) obtained by digesting flue gas desulfurized gypsum lime with high purity lime (Ca (OH) 2 content of 90 to 98% In order to prevent the drying shrinkage of blast furnace slag, one or more anhydrous gypsum selected from natural anhydrous gypsum, flue gas desulfurization gypsum and chemical anhydrous gypsum is applied.

In order to secure the pot life, moisturizing property, and adhesion property necessary for the construction of the tile adhesive, a composition including a methylcellulose thickener, a re-powdered powder EVA resin, a calcium formate curing accelerator, We tried to secure a quality performance equal to or better than existing tile adhesives.

The present invention for solving the various disadvantages and problems of the prior uncemented technique, with as energy and CO2 reduction problem as described above, blast furnace slag 100kg parts by contrast, natural anhydrite (SO3 content of 54-56%), flue gas desulfurization (Ca (OH) 2 content of 80 to 90%), high purity calcium hydroxide (Ca (OH) 2 content of 90 to 98%), and anhydrous gypsum of 2 to 10 kg, 1 to 7 kg of any one or more slaked lime selected from the group consisting of modified gypsum lime (Ca (OH) 2 50-60% + CaSO4 50-40%) obtained by digesting flue gas desulfurized gypsum lime, 3 to 9 kg of limestone fine powder, 0.2 to 1 kg of a methylcellulose thickener, 0.2 to 1.2 kg of a re-oiled powder EVA resin, 0.2 to 1.2 kg of a calcium formate hardening accelerator, 150 to 180 kg of silica Based on an environmentally friendly white tile adhesive composition, blast furnace slag, , A calcium lactate thickening agent, a re-lubrication type powder EVA resin, and a calcium formate hardening accelerator are first mixed in a powder form in a uniform manner in a mixing mixer, And a method for manufacturing an eco-friendly white tile adhesive made of mortar through a two-step process of mixing silica sand having a particle size of 1.0 to 4.0.

The present invention can reduce a large amount of energy consumption consumed in the production process of existing white cement by using blast furnace slag powder which is an industrial byproduct compared with the conventional tile adhesive using the white cement, Can be reduced as shown in Table 1 below,

List of energy consumption and CO2 emission amount when manufacturing 1 ton of white cement Category / Type White cement Environment friendly cement binder Energy and CO2
Reduction rate CO2 Emission Approximately 830kg Approximately 192kg About 77%

If the annual consumption of existing white cement is 250,000 tons, it is environmentally friendly and economical because it has energy and CO2 reduction effect as shown in Table 2 below.

250,000 tons of white cement applied to the market Reduction rate of energy and CO2 emissions Category / Type White cement Environment friendly cement binder Energy and CO2
Reduction rate CO2 Emission About 207,500 tons About 4,800 tons About 77%

1 is a photograph showing the degree of adhesion of a tile adhesive according to an embodiment of the present invention.

In order to achieve the above object, in the present invention is blast furnace slag 100kg parts by contrast, natural anhydrite (SO3 content of 54-56%), FGD gypsum, chemical anhydrite as compared to the tile adhesive with conventional white cement (Ca (OH) 2 content 80 to 90%), high purity lime (Ca (OH) 2 content 90 to 98%), flue gas desulfurization gypsum lime is digested 1 to 7 kg of at least one selected from the group consisting of modified gypsum lime (Ca (OH) 2 50 to 60% + CaSO 4 50 to 40%), and 3 to 9 kg of limestone fine powder, 0.2 to 1 kg, 0.2 to 1.2 kg of re-oil type powder EVA resin, 0.2 to 1.2 kg of calcium formate based curing accelerator, and 150 to 180 kg of silica .

  In the present invention, the blast furnace slag fine powder is preferably a blast furnace slag powder having a degree of whiteness of 90% or more as compared to the white cement. It is preferable to use a silica sand having a granularity of 1.0 to 4.0 Do.

The present invention also provides a process for producing an eco-friendly white tile adhesive using industrial by-products, which comprises blending a blast furnace slag, anhydrous gypsum, slaked lime, a limestone fine powder, a methylcellulose thickener, a reflux type powder EVA resin, A curing accelerator is firstly mixed in a powder form and uniformly mixed in a mixing mixer and then mixed with silica having a granularity of 5.0 to 4.0 mm and a granulation degree of 1.0 to 4.0 to prepare an eco-friendly white tile adhesive And a method for producing the same.

Hereinafter, embodiments of the present invention will be described, but these are for illustrative purposes only and do not limit the scope of the present invention.

Example 1

100 kg of blast furnace slag powder, 2 kg of natural anhydrous gypsum, 1 kg of general slaked lime, 3 kg of limestone fine powder, 0.2 kg of methylcellulose thickener, 0.2 kg of re-oiled powder EVA resin, 0.2 kg of calcium formate type hardening accelerator, Friendly white tile adhesive.

Example 2

Composed of 100 kg of blast furnace slag, 6 kg of natural anhydrous gypsum, 1 kg of general slaked lime, 3 kg of limestone fine powder, 0.2 kg of methylcellulose thickener, 0.2 kg of re-fired powder EVA resin, 0.2 kg of calcium formate type hardening accelerator, Friendly white tile adhesive.

Example 3

100 kg of blast furnace slag, 10 kg of natural anhydrous gypsum, 1 kg of general slaked lime, 3 kg of limestone fine powder, 0.2 kg of methylcellulose thickener, 0.2 kg of re-fired powder EVA resin, 0.2 kg of calcium formate type hardening accelerator, Friendly white tile adhesive.

Example 4

100 kg of blast furnace slag, 6 kg of natural anhydrous gypsum, 4 kg of general slaked lime, 3 kg of limestone fine powder, 0.2 kg of methylcellulose thickener, 0.2 kg of re-fired powder EVA resin, 0.2 kg of calcium formate hardening accelerator, Friendly white tile adhesive.

Example 5

Composed of 100 kg of blast furnace slag, 6 kg of natural anhydrous gypsum, 7 kg of general slaked lime, 3 kg of limestone fine powder, 0.2 kg of methylcellulose thickener, 0.2 kg of re-fired powder EVA resin, 0.2 kg of calcium fomade type hardening accelerator, Friendly white tile adhesive.

Example 6

Composed of 100 kg of blast furnace slag, 6 kg of natural anhydrous gypsum, 4 kg of ordinary slaked lime, 6 kg of limestone fine powder, 0.4 kg of methylcellulose thickener, 0.2 kg of re-fired powder EVA resin, 0.2 kg of calcium formate- Friendly white tile adhesive.

Example 7

Composed of 100 kg of blast furnace slag, 6 kg of natural anhydrous gypsum, 4 kg of general slaked lime, 9 kg of limestone fine powder, 0.2 kg of methylcellulose thickener, 0.2 kg of re-oiled powder EVA resin, 0.2 kg of calcium formate type hardening accelerator, Friendly white tile adhesive.

Example 8

Composed of 100 kg of blast furnace slag, 6 kg of natural anhydrous gypsum, 4 kg of general slaked lime, 6 kg of limestone fine powder, 0.6 kg of methylcellulose thickener, 0.7 kg of re-oiled powder EVA resin, 0.6 kg of calcium formate- Friendly white tile adhesive.

Example 9

100 kg of blast furnace slag powder, 6 kg of natural anhydrous gypsum, 4 kg of general slaked lime, 6 kg of limestone fine powder, 1.0 kg of methylcellulose thickener, 0.7 kg of re-oiled powder EVA resin, 0.6 kg of calcium formate- Friendly white tile adhesive.

Example 10

Composed of 100 kg of blast furnace slag, 6 kg of natural anhydrous gypsum, 4 kg of general slaked lime, 6 kg of limestone fine powder, 0.6 kg of methylcellulose thickener, 0.7 kg of re-oiled powder EVA resin, 0.2 kg of calcium formate type hardening accelerator, Friendly white tile adhesive.

Example 11

100 kg of blast furnace slag, 6 kg of natural anhydrous gypsum, 4 kg of general slaked lime, 6 kg of limestone fine powder, 0.6 kg of methylcellulose thickener, 1.2 kg of re-fired powder EVA resin, 0.2 kg of calcium formate- Friendly white tile adhesive.

Example 12

Composed of 100 kg of blast furnace slag, 6 kg of natural anhydrous gypsum, 4 kg of general slaked lime, 6 kg of limestone fine powder, 0.6 kg of methylcellulose thickener, 0.7 kg of re-oiled powder EVA resin, 0.7 kg of calcium formate- Friendly white tile adhesive.

Example 13

Composed of 100 kg of blast furnace slag, 6 kg of natural anhydrous gypsum, 4 kg of general slaked lime, 6 kg of limestone fine powder, 0.6 kg of methylcellulose thickener, 0.7 kg of re-oiled powder EVA resin, 1.2 kg of calcium formate- Friendly white tile adhesive.

Example 14

Composed of 100 kg of blast furnace slag, 6 kg of natural anhydrous gypsum, 4 kg of general slaked lime, 6 kg of limestone fine powder, 0.6 kg of methylcellulose thickener, 0.7 kg of re-oiled powder EVA resin, 0.7 kg of calcium formate- Friendly white tile adhesive.

Example 15

Composed of 100 kg of blast furnace slag, 6 kg of natural anhydrous gypsum, 4 kg of ordinary slaked lime, 6 kg of limestone fine powder, 0.6 kg of methylcellulose thickener, 0.7 kg of re-oiled powder EVA resin, 0.7 kg of calcium formate- Friendly white tile adhesive.

Comparative Example 1

An eco-friendly white tile adhesive composed of 100 kg of white cement, 6 kg of limestone fine powder, 0.6 kg of methylcellulose thickener, 0.7 kg of re-oiled powder EVA resin, 0.7 kg of calcium formate curing accelerator, and 180 kg of silica sand was prepared.

Experimental Example

Experimental Example 1

 In Examples 1, 2 and 3, the shrinkage ratio was compared as an experiment to compare the quality characteristics according to the content of anhydrous gypsum in the composition of the tile adhesive. The dry shrinkage rate was measured by filling each of the water mixed bombarded mortars with a mold having a size of 40 mm x 40 mm 160 mm and then measuring the initial length with a micrometer gauge after demolding at a temperature of 202 and a saturation humidity for 72 hours. After curing for 7 days in% curing condition, the later length of the mortar was measured and the rate of shrinkage length change of the mortar was calculated as a percentage.

Dry shrinkage according to anhydrous gypsum content division Dry shrinkage (%) Example 1 -0.10 Example 2 -0.05 Example 3 -0.04 Comparative Example 1 -0.06

Experimental Example 2

In Examples 2, 4 and 5, the compressive strength values were compared with each other in order to compare the quality characteristics of the composition of the tile adhesive with changes in the content of the slaked lime. The curing conditions of the specimens were cured at a standard temperature of 202 and a humidity of 655%.

The compressive strength division Compressive strength at 28 days (N / mm2) Example 2 8.7 Example 4 10.4 Example 5 9.2 Comparative Example 1 10.1

Experimental Example 3

 In Examples 4, 6 and 7, compressive strength values were compared as an experiment to compare the quality characteristics according to the content of the limestone fine powder in the composition of the tile adhesive. The curing conditions of the specimens were cured at a standard temperature of 202 and a humidity of 655%.

Compressive Strength at 28 days of age according to limestone contents division Compressive strength at 28 days (N / mm2) Example 4 10.4 Example 6 10.9 Example 7 10.6 Comparative Example 1 10.1

Experimental Example 4

Examples 6, 8, and 9 are experiments for comparing the quality characteristics according to the content of the methylcellulose thickener in the composition of the tile adhesive, and compared the water retention values.

The rate of water retention according to methylcellulose thickener content division Remaining rate (%) Example 6 81 Example 8 84 Example 9 88 Comparative Example 1 85

Experimental Example 5

In Examples 8, 10 and 11, adhesion strength was compared as an experiment to compare the quality characteristics according to the content of re-oil type powder EVA resin in the composition of the tile adhesive. Bond strength The curing conditions of the specimens were cured at a standard temperature of 202 and a humidity of 655%.

Resin Type Powder EVA Bond strength at 28 days division Bond strength at 28 days (N / mm2) Example 8 0.57 Example 10 0.72 Example 11 0.66 Comparative Example 1 0.60

Experimental Example 6

 In Examples 10, 12 and 13, the compaction time was compared as an experiment to compare the quality characteristics according to the content of the calcium formate curing accelerator in the composition of the tile adhesive.

Coagulation time according to content of calcium formate hardening accelerator division Condensation time (hours) Example 10 39 Example 12 25 Example 13 18 Comparative Example 1 52

Experimental Example 7

Examples 12, 14, and 15 compare the quality characteristics of the tile adhesive composition as an experiment to compare the quality characteristics according to the content of silica sand.

Weathering due to silica content division Unfinished Example 12 ★★★★ Example 14 ★★★★★ Example 15 ★★★★ Comparative Example 1 ★★★★★

Experimental Example 8

The whiteness of the tile adhesive composition prepared in Examples 2, 6, and 10 was compared with that of Comparative Example 1.

Whiteness comparison test division Whiteness (%) Example 2 90.3% Example 6 90.4% Example 10 90.3% Comparative Example 1 90.7%

Claims (4)

In an environmentally friendly white tile adhesive composition,
Blast furnace slag 100kg parts by contrast, natural anhydrite (SO3 content of 54 ~ 56%), including anhydrite 2 ~ 10kg least any one selected from FGD gypsum, chemical anhydrous gypsum, and the general calcium hydroxide (Ca (OH) 2 (Ca (OH) 2 50-40%) and refined gypsum lime (Ca (OH) 2 50 ~ 60% + CaSO4) which is obtained by digesting flue gas desulfurized gypsum lime 1 to 7 kg of selected at least one slaked lime selected from the group consisting of calcium carbonate, calcium carbonate, calcium carbonate, calcium carbonate, Wherein the composition comprises 0.2 to 1.2 kg of a foam-based curing accelerator and 150 to 180 kg of silica sand.
The eco-friendly white tile adhesive composition according to claim 1, wherein the fine powder of blast furnace slag has a whiteness of 90% or more as compared to white cement.
The eco-friendly white tile adhesive composition according to claim 1, wherein the silica sand has a particle size of 1.0 to 4.0 with a white color of 5.0 mm or less.
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