KR101410056B1 - A Concrete Using Non-sintering Binder Having Bottom Ash - Google Patents

Abstract

The present invention relates to a non-sintered binder containing bottom ash. More specifically, the present invention relates to a non-sintered binder containing a bottom ash in an appropriate ratio in place of cement which discharges a large amount of carbon dioxide by plastic working, a binder in which sodium hydroxide and sodium silicate are mixed with an alkali activator Which can provide a cementless mortar or concrete with a compressive strength of 50 MPa when producing mortar or concrete by using such a binder, can be provided by using a bottom ash which is non- .

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a cement based non-sintering binder having a bottom ash,

The present invention relates to a non-sintered binder containing bottom ash. More specifically, the present invention relates to a non-sintered binder containing a bottom ash in an appropriate ratio in place of cement which discharges a large amount of carbon dioxide by plastic working, a binder in which sodium hydroxide and sodium silicate are mixed with an alkali activator Which can provide a cementless mortar or concrete with a compressive strength of 50 MPa when producing mortar or concrete by using such a binder, can be provided by using a bottom ash which is non- .

As a global effort to prevent global warming, various forms of efforts have been put in place (adopted in 1997, ending the Kyoto Protocol in 2012, which came into force in 2005), and in December 2007, the Bali Roadmap was adopted in Bali, Indonesia. Negotiations are under way for the Convention on Climate Change. As a result, global emissions of carbon dioxide and other greenhouse gases have to be significantly reduced.

On the other hand, since the cement industry is a major carbon dioxide emission industry along with the steel industry, it produces about 1 ton of carbon dioxide to produce 1 ton of cement which is the base of concrete production. Therefore, Is urgently required.

Domestic cement production amounts to about 60 million tons per year, which produces about 54 million tons of carbon dioxide. As a countermeasure against such environmental pollution, researches for replacing cement using industrial byproducts are continuously being carried out. Domestic and foreign blast furnace slag, meta kaolin, etc. are mixed with cement to some extent and applied to concrete. However, this method has a limit to reduce carbon dioxide remarkably.

Outside of the world, the concept of alkaline activated cement (concrete) by polymerization reaction was conceptually established by Davidovits (France) in 1978 using kaolinite minerals as a mechanism to have a structure similar to zeolite. However, But it was not put into practical use due to economic reasons.

Although meta-kaolin is used in the prior art, since kaolin is calcined at 700-800 DEG C and meta kaolin is used, carbon dioxide is discharged in this process, and the cost is high, so there is a problem in practical use.

Among fly ash generated from thermal power plants, fly ash (fly ash) is mostly consumed by cement raw materials and concrete admixtures. However, bottom ash (bottom ash), which accounts for 15 ~ 25% Is largely disposed of in landfills, which is a factor that hinders the economic loss due to huge treatment costs and the efficient utilization of the land due to landfill increase. Therefore, studies on cement mortar or concrete using bottom ash with cement as an alternative material are under way.

Accordingly, the present inventors have conducted research and experiments to use bottom ash as a binder for mortar or concrete. The present invention has been made in view of the fact that instead of cement which discharges a large amount of carbon dioxide during manufacturing, The present invention provides a binder capable of producing cement mortar or cement concrete excellent in workability and compressive strength by mixing sodium hydroxide and sodium silicate in an appropriate ratio as an alkali activating agent.

In order to accomplish the above object, the non-sintered binder containing the bottom ash of the present invention comprises a bottom ash and an alkaline activator composed of an alkaline hydroxide and a silicate, wherein the alkali activator with respect to the bottom ash is 55% to 65% %.

The bottom ash refers to coal ash that has been attached to the wall of the furnace during pulverizing coal combustion and has fallen on the bottom of the boiler due to its own weight. Such bottom ash reacts with the alkaline activator to cause curing by separate aggregation with Si and Al components .

The curing process of the mortar or concrete to which the binder of the present invention is applied can be classified into 1) formation of precursors through synthesis of hydroxide ions, 2) partial reconstitution of alkali-silica, and 3) reprecipitation for forming inorganic structure .

Thus, in the mortar or concrete to which the binder of the present invention is applied, the ratio of Al / Si and the ratio of H2O / SiO2 are also important. H2O plays an important role in the dissolution process of aluminum and silica ions.

In the present invention, polymerization is induced by the combination of the bottom ash and the alkali activator composed of an alkali hydroxide and a silicate to increase the strength, so that the cement is not used, To provide a binding material that can be used.

In the present invention, sodium hydroxide is preferably used as the alkaline hydroxide, and sodium silicate is preferably used as the silicate. The binder of the present invention is composed of bottom ash (A), sodium hydroxide (B) and sodium silicate (C), wherein the ratio of sodium hydroxide and sodium silicate (B + C) to bottom ash It is valid that the weight ratio ((B + C) / A) is comprised between 55% and 65%. When the weight ratio (A: B + C) of the alkali activator to the bottom ash of the binder is 55% to 65%, suitable proportions of Si, Al and Na are present in the polymerization reaction. Is less than 55%, the amount of Na required for the reaction is relatively insufficient and the strength is lowered. On the other hand, when the weight ratio exceeds 65%, Si or Al contributing to the strength is insufficient, The amount of water contained in the slurry is increased and the slump is increased. However, in addition to the water required for the dissolution process of aluminum and silica ions, the residual moisture causes a decrease in strength, so that the compounding ratio is limited as described above.

It is preferable that the weight ratio of sodium hydroxide and sodium silicate constituting the alkaline activator is 1: 1, because when the sodium hydroxide is used in a large amount, the molar concentration of the mixed solution decreases and the condensation phenomenon occurs, Which causes a decrease in strength. On the contrary, when sodium hydroxide is used in a small amount, the production of aluminosilicate decreases at the beginning of the age, and the initial strength is lowered and the shrinkage is somewhat increased. In addition, since a large amount of sodium silicate is used in order to reinforce this, There is a problem in that it is limited.

It is preferable that the bottom ash has a powder degree of 3,800 to 4,100 cm < 2 > / g. This is because the bottom ash raw material has a powdery degree of 1,500 to 1,700 cm & g or more, the reactivity is high, but the workability is poor, and it takes a long time to make the fine powder, so that the economical efficiency may be lowered.

The sodium silicate preferably has a molar ratio of SiO ₂ to Na ₂ O in the range of 1.0 to 3.4. When the molar ratio is less than 1.0, the viscosity of the binder is drastically increased to lower the slump, In addition, when the molar ratio exceeds 3.4, there is no influence on the workability, but there is a problem that the initial strength is reduced due to a decrease in Na ions . Furthermore, in order to obtain better workability and strength, it is more preferable to use sodium silicate having a molar ratio of SiO ₂ to Na ₂ O of 2.8 to 3.2.

Sodium hydroxide is used as the alkaline hydrate, and sodium hydroxide in the range of 6 to 16 M is preferred. If less than 6M is used, the amount of the bottom ash is less than the amount required for the reaction, and sufficient alkali activation reaction does not occur, thereby reducing the strength. When the amount of the alkaline hydrate exceeding 16M is used, Since the effect of improving the strength is insignificant, it is disadvantageous in terms of economy.

In the present invention, the cement mortar may be formed by blending fine aggregate and water in the non-sintered binder containing the bottom ash mentioned above. By blending coarse aggregate, fine aggregate and water into the non-sintered binder containing bottom ash Cementless concrete can be constructed. In such mortar and concrete, admixture and reinforcing fiber can be reinforced if necessary.

The non-sintered binder containing the bottom ash of the present invention as described above can maintain a compressive strength of 30 to 50 MPa at high temperature curing depending on the mixing ratio thereof, thereby providing cement mortar or cementitious concrete.

In addition, the non-sintered binder including the bottom ash of the present invention has a merit that the fluidity can be maintained for a predetermined time or more during the production of mortar or concrete, thereby ensuring sufficient workability and sufficient applicability as a binder.

Further, since the cement is completely replaced by using the non-sintered binder including the bottom ash of the present invention, a large amount of CO ₂ Gas generation can be reduced and the bottom ash, which is an industrial by-product, is recycled, which not only has an economic burden for securing a landfill, but also has the advantage of reducing many environmental problems caused by leachate generated during landfilling.

1 is a graph showing a slump result and a compressive strength result according to a mass ratio of an alkaline activator and bottom ash as a binder material.
FIG. 2 is a graph showing a slump result and a compressive strength result according to a mixing ratio of an alkaline activator as a binder component material, that is, a mixing ratio of sodium silicate and sodium hydroxide.

Hereinafter, the present invention will be described in more detail with reference to Examples.

The embodiments according to the present invention can be modified into various other forms, and thus the scope of the present invention is not limited to the embodiments described below.

In an embodiment of the present invention, an experiment example based on two conditions is presented in order to analyze the influence of the bottom ash and the alkali activating agent (sodium hydroxide, sodium silicate) in the mortar production using the inventive binder. First, the influence of the weight ratio of alkali activator on the bottom ash was analyzed. At this time, sodium hydroxide and sodium silicate constituting the alkaline activator are mixed at a weight ratio of 1: 1. Secondly, the relative weight of the bottom ash and the relative weight of the alkaline activator were fixed, and the effect of the mixing ratio between sodium hydroxide and sodium silicate constituting the alkaline activator was analyzed.

≪ Example 1 >

Alkaline activator  Weight ratio effect

Powder 100 the weight ratio of 4,000㎠ / g bottom ash, bottom ash and an alkali activator in an alkaline activation (sodium hydroxide _{(NaOH) 9M, SiO 2 /} Na 2 O of the sodium silicate mole ratio of 3.2) with claim 55, 100: 60, 100: 65, 100: 70, wherein a weight ratio of sodium hydroxide to sodium silicate is 1: 1, and the fine aggregate is composed of SiO ₂ component 99.7% were used.

The thus-prepared mortar was subjected to a slump test in accordance with KS L 5111, and a 50 × 50 × 50 mm cube specimen was prepared, cured at 60 ° C. for 2 days, demolded and then cooled to room temperature (humidity 50 ± 5% 2 ° C) and measured according to KS F 5105 at 28 days of age. The results are summarized in Fig.

1, when the relative weight ratio of the alkaline activator to the bottom ash weight was less than 55%, the compressive strength was good but the slump was small. When the relative weight ratio was 60 to 65%, the slump and compressive strength were good But when it exceeds 65%, the slump becomes large and the strength decreases. That is, Si and Al and Na are present in appropriate proportions required for the polymerization reaction, but the weight of bottom ash is constant. However, when the amount of alkali activator is large, Si or Al contributing to the strength is insufficient, The amount of water contained in the slurry increases as the amount of water contained in the slurry increases. However, the residual moisture in addition to the water required for the dissolution process of the aluminum and silica ions causes the decrease in strength. Therefore, it is judged that the relative weight ratio of the alkali activating agent to the bottom ash weight is in the range of 55% to 65% in terms of the strength and the slump, and more preferably, the relative weight ratio of the alkali activating agent to the bottom ash weight is 60 to 65 %.

≪ Example 2 >

Sodium hydroxide and Sodium silicate  Weight ratio effect

Fineness but blended 4,000㎠ / g Bottom ash, alkali activator (sodium hydroxide (NaOH) of sodium silicate 9M, the molar ratio of SiO ₂ / Na ₂ O 3.2) having, a bottom ash, as seen in Example 1 And an alkaline activator were mixed at an appropriate weight ratio of 100: 60, and a weight ratio of sodium silicate and sodium hydroxide constituting the double alkali activator was 20:40, 30:30, 36:24, and 40:20, respectively Respectively. That is, the fine aggregate is minimized in the binding material in which the alkali activator: sodium silicate: sodium hydroxide is blended with 100: 20: 40, 100: 30: 30, 100: 36: 24, and 100: For this purpose, silica sand with a SiO ₂ content of 99.7% was used.

In this embodiment, the thus prepared mortar was subjected to a slump test in accordance with KS L 5111, a 50 × 50 × 50 mm cube test specimen was prepared, cured at 60 ° C. for 2 days, demolded and then cooled to room temperature (humidity: 50 ± 5% , Temperature: 20 ± 2 ° C) and measured according to KS F 5105 at 28 days of age. The results are summarized in FIG.

2, when the relative weight ratio of the bottom ash and the alkali activator is constant, the mixing ratio of sodium silicate to sodium hydroxide is 20:40 (1: 2) (corresponding to 0.5 in the horizontal axis in FIG. 2) But it was small in terms of early strength and long term strength. In this case, when the amount of sodium hydroxide is increased, the content of water is increased and the slump is increased, but it is judged that the Si component of sodium silicate is relatively insufficient, which causes the strength to be lowered. In the case where the mixing ratio is 36:24 (1.5: 1) (corresponding to the abscissa axis 1.5 in FIG. 2) and 40:20 (2: 1) (corresponding to the abscissa axis 2 in FIG. 2), the slump is constant, . In this case, as the amount of sodium silicate increases, the viscosity of the activator increases, the slump decreases, and the Na component of sodium hydroxide is relatively insufficient. Therefore, as can be seen from the present embodiment, in consideration of the slump value contributed by the moisture content in sodium hydroxide, and the strength of sodium hydroxide and sodium silicate contributed by Si, the most preferable ratio of the alkaline activator is sodium silicate It is judged to be appropriate that sodium hydroxide is blended in a weight ratio of 1: 1.

From the above results, when the weight ratio of the alkali activator to the bottom ash is 55% to 65% and the weight ratio of sodium silicate and sodium hydroxide is 1: 1, the mortar composition of the bottom ash, sodium hydroxide, Or concrete exhibits excellent workability and compressive strength, so that the binder of the present invention can completely replace the cement.

Claims (8)

Wherein the alkali activator comprises 60-65% by weight of the bottom ash, wherein the alkali activator is selected from the group consisting of sodium hydroxide, The weight of the alkaline hydroxide and the silicate is 1: 1 , the bottom ash is 3,800 to 4,100 cm < 2 > / g, and the amount of the alkaline hydroxide and the silicate is 3,800 to 4,100 cm < 2 > / g in consideration of the slump contributed by the sodium hydroxide , Wherein the alkaline hydroxide is sodium hydroxide in the range of 6 to 16 M, the silicate is sodium silicate, and the sodium silicate is a mixture of SiO ₂ and Na ₂ O in a molar ratio of 1.0 to 3.4. Became,
Wherein the slump flow is 150 mm or more and the 28-day compressive strength is 50 MPa or more . delete delete delete delete delete delete delete

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