Inorganic recycled concrete aggregate

文档序号:460601 发布日期:2021-12-31 浏览:5次 中文

阅读说明:本技术 一种无机再生混凝土集料 (Inorganic recycled concrete aggregate ) 是由 汤开军 翁坚壮 高青峰 于坤 于 2021-10-30 设计创作,主要内容包括:本申请涉及混凝土领域,具体公开了一种无机再生混凝土集料;由包含以下重量份的原料制成:水泥200-280份、粉煤灰100-150份、矿粉20-60份、再生粗骨料950-1500份、外加剂5-8.4份、水110-145份;再生粗骨料采用如下方法制备而成:Ⅰ废旧混凝土块经破碎、清洗、分级、烘干后制得再生集料;Ⅱ再生集料经明胶溶液预处理,然后经干燥,制得预处理再生集料;Ⅲ预处理再生集料经疏水改性硅溶胶再处理,制得再生粗骨料;使制得的再生混凝土具有机械强度好的优点。(The application relates to the field of concrete, and particularly discloses an inorganic recycled concrete aggregate; the feed is prepared from the following raw materials in parts by weight: 280 parts of cement, 100 parts of fly ash, 150 parts of mineral powder, 20-60 parts of recycled coarse aggregate, 950-1500 parts of admixture and 145 parts of water; the recycled coarse aggregate is prepared by the following method: i, crushing, cleaning, grading and drying waste concrete blocks to obtain regenerated aggregates; II, pretreating the regenerated aggregate by using a gelatin solution, and then drying to prepare pretreated regenerated aggregate; III, carrying out retreatment on the pretreated recycled aggregate through hydrophobic modified silica sol to prepare recycled coarse aggregate; the prepared recycled concrete has the advantage of good mechanical strength.)

1. The inorganic recycled concrete aggregate is characterized by being prepared from the following raw materials in parts by weight: 280 parts of cement, 100 parts of fly ash, 150 parts of mineral powder, 20-60 parts of recycled coarse aggregate, 950-1500 parts of admixture and 145 parts of water;

the recycled coarse aggregate is prepared by the following method:

i, crushing, cleaning, grading and drying waste concrete blocks to obtain regenerated aggregates;

II, pretreating the regenerated aggregate by using a gelatin solution, and then drying to prepare pretreated regenerated aggregate;

III, carrying out retreatment on the pretreated recycled aggregate by using the hydrophobic modified silica sol to prepare recycled coarse aggregate.

2. An inorganic recycled concrete aggregate according to claim 1, characterized in that: the pretreatment comprises the following steps:

preparing a gelatin solution with the mass fraction of 0.1-0.7%, then placing the regenerated aggregate into the gelatin solution for soaking, wherein the mass ratio of the regenerated aggregate to the gelatin solution is 1:1.5-2.5, the temperature is maintained at 40-50 ℃ in the soaking process, and the regenerated aggregate is taken out after soaking for 15-25 min.

3. The inorganic recycled concrete aggregate as recited in claim 2, wherein said soaking process is continuously performed at a rotation speed of 800-2000 r/min.

4. The inorganic recycled concrete aggregate of claim 1, wherein said hydrophobically modified silica sol is silica sol modified with methyltriethoxysilane.

5. Inorganic recycled concrete aggregate according to claim 1, characterized in that said reprocessing comprises the following steps:

firstly, spraying hydrophobic modified silica sol on the surface of the pretreated regenerated aggregate, wherein the weight ratio of the pretreated regenerated aggregate to the hydrophobic modified silica sol is 1:0.05-0.15, and drying to obtain a primary coating material;

secondly, spraying hydrophobic modified silica sol on the surface of the primary coating material again, wherein the weight ratio of the primary coating material to the hydrophobic modified silica sol is 1:0.1-0.2, and preparing a secondary coating material after spraying is finished;

thirdly, spraying a filler on the surface of the secondary coating material, wherein the weight ratio of the secondary coating material to the filler is 1:0.02-0.1, and then drying.

6. An inorganic recycled concrete aggregate according to claim 5, characterised in that said filler consists of titanium dioxide, composite fibres in a weight ratio of 0.6-1: 1.

7. The inorganic recycled concrete aggregate of claim 6, wherein said composite fibers consist of glass fibers and alumina fibers in a weight ratio of 1: 1-3.

8. The inorganic recycled concrete aggregate of claim 1, wherein the admixture is a water reducing agent.

9. The inorganic recycled concrete aggregate of claim 8, wherein said water-reducing agent is a polycarboxylic acid high-efficiency water-reducing agent.

Technical Field

The present application relates to the field of concrete, and more particularly, it relates to an inorganic recycled concrete aggregate.

Background

Along with the development of society, the building waste of cities is increasing day by day, but the quantity of natural sandstone resources in China is reduced year by year, and in order to ensure the demand of China on the quantity of concrete, the recycled concrete is gradually concerned.

The regenerated concrete aggregate is prepared by crushing, cleaning and grading waste concrete blocks, mixing the crushed, cleaned and graded waste concrete blocks with a grading agent according to a certain proportion, partially or completely replacing natural aggregates such as sand stones and the like, and adding cement, water and the like to prepare new concrete.

The waste concrete can be subjected to a large external force in the crushing process, a large number of fine cracks can appear in the aggregate, and the water absorption rate of the regenerated aggregate are far higher than those of natural coarse aggregates, so that the mechanical strength of the regenerated concrete is influenced.

Disclosure of Invention

In order to make a better recycled concrete of compressive strength, rupture strength, this application provides an inorganic recycled concrete aggregate.

The application provides an inorganic recycled concrete aggregate adopts following technical scheme:

an inorganic recycled concrete aggregate is prepared from the following raw materials in parts by weight: 280 parts of cement, 100 parts of fly ash, 150 parts of mineral powder, 20-60 parts of recycled coarse aggregate, 950-1500 parts of admixture and 145 parts of water;

the recycled coarse aggregate is prepared by the following method:

i, crushing, cleaning, grading and drying waste concrete blocks to obtain regenerated aggregates;

II, pretreating the regenerated aggregate by using a gelatin solution, and then drying to prepare pretreated regenerated aggregate;

III, carrying out retreatment on the pretreated recycled aggregate by using the hydrophobic modified silica sol to prepare recycled coarse aggregate.

Through adopting above-mentioned technical scheme, the reclaimed aggregate is in proper order through gelatin solution, hydrophobic modified silica sol solution is handled, at first utilize the effect of absorbing gelatin solution of reclaimed aggregate's water absorption for gelatin solution can get into the inside pore structure of reclaimed aggregate and the cladding is on the reclaimed aggregate surface, form gelatin filling material after the gelatin solution is dry, thereby fill in the hole of reclaimed aggregate inner structure, the cover effect of cooperation gelatin prevents the reclaimed coarse aggregate to stir the in-process at the concrete and excessively absorbs the mix water tentatively.

Then, the pretreated recycled aggregate is treated by hydrophobic modified silica sol, and the hydrophobic effect of the hydrophobic modified silica sol is utilized to enable adjacent recycled coarse aggregates to repel each other, so that sand in the recycled coarse aggregates is conveniently filled in the holes of the space structure of the crushed stones, cement is conveniently filled in the holes of the space structure of the adjacent sand of the recycled coarse aggregates, and the compactness of the internal structure of the concrete is improved; and the hydrophobic effect of the hydrophobic modified silica sol is matched, so that the regenerated coarse aggregate is further prevented from excessively absorbing the moisture in the concrete mixture.

The recycled concrete prepared by the recycled coarse aggregate has better mechanical strength by avoiding the excessive absorption of the recycled coarse aggregate and mixing water, and the recycled concrete further has better mechanical strength by matching with better structural density between the recycled coarse aggregate and cement particles.

Preferably, the pretreatment comprises the following steps:

preparing a gelatin solution with the mass fraction of 0.1-0.7%, then placing the regenerated aggregate into the gelatin solution for soaking, wherein the mass ratio of the regenerated aggregate to the gelatin solution is 1:1.5-2.5, the temperature is maintained at 40-50 ℃ in the soaking process, and the regenerated aggregate is taken out after soaking for 15-25 min.

By adopting the technical scheme, the regenerated aggregate is soaked in the gelatin solution with proper mass fraction, the gelatin solution is always maintained in the solution state at the temperature of 40-50 ℃, the coagulation phenomenon cannot occur, and the gelatin solution can partially enter pores on the surface of the regenerated aggregate and partially adsorb the surface of the regenerated aggregate by utilizing the fluidity of the gelatin solution; after soaking, preparing the pretreated regenerated aggregate by matching with subsequent drying operation, loading dried gelatin substances on the surface and in the pores of the pretreated regenerated aggregate, filling the pores in the regenerated aggregate by utilizing the solid property of the dried gelatin substances, and partially adhering the dried gelatin substances to the surface of the regenerated aggregate, thereby preventing the pores on the surface of the regenerated aggregate from excessively absorbing water, and enabling the finished concrete to have better mechanical strength.

Preferably, the stirring is continuously carried out at the rotating speed of 800-2000r/min in the soaking process.

By adopting the technical scheme, the regenerated aggregate is uniformly contacted with the gelatin solution, so that the regenerated aggregate is uniformly filled and coated by the gelatin solution, and the finished concrete has better mechanical strength.

Preferably, the hydrophobically modified silica sol is prepared by modifying silica sol with methyl triethoxysilane.

By adopting the technical scheme, the silicon sol is subjected to hydrophobic modification treatment by adopting the methyltriethoxysilane, so that the silicon sol has a good hydrophobic effect while having a proper viscosity, and methyl groups with strong hydrophobicity are loaded on the surface of the silicon sol.

The more uniform dispersion structure of the recycled coarse aggregate can prevent the phenomenon of regional excessive water absorption in the concrete, namely the recycled coarse aggregate is gathered to easily cause the local water absorption in the concrete to be excessively increased, thereby easily influencing the mechanical strength in the concrete; meanwhile, the internal structure of the concrete can be more compact due to the uniform dispersion structure, so that the mechanical strength of the finished concrete is further improved.

Preferably, the reprocessing comprises the steps of:

firstly, spraying hydrophobic modified silica sol on the surface of the pretreated regenerated aggregate, wherein the weight ratio of the pretreated regenerated aggregate to the hydrophobic modified silica sol is 1:0.05-0.15, and drying to obtain a primary coating material;

secondly, spraying hydrophobic modified silica sol on the surface of the primary coating material again, wherein the weight ratio of the primary coating material to the hydrophobic modified silica sol is 1:0.1-0.2, and preparing a secondary coating material after spraying is finished;

thirdly, spraying a filler on the surface of the secondary coating material, wherein the weight ratio of the secondary coating material to the filler is 1:0.02-0.1, and then drying.

By adopting the technical scheme, the hydrophobic modified silica sol is sprayed on the surface of the pretreated regenerated aggregate for the first time, and the spraying amount is limited, so that the hydrophobic modified silica sol is coated on the surface of a gelatin substance, the gelatin substance on the surface of the pretreated regenerated aggregate is prevented from being damaged by the hydration heat of concrete during hardening, and after the gelatin filling substance on the surface of the regenerated aggregate is damaged, the surface of the regenerated aggregate is easy to absorb water again, and the mechanical strength of the concrete is influenced; therefore, the preliminarily coated hydrophobic modified silica sol not only can enable the regenerated aggregate to have a hydrophobic effect, but also can prevent the regenerated aggregate from absorbing water, so that the finished product has better mechanical strength.

After the hydrophobic modified silica sol is sprayed for the second time, the filler is sprayed while the hydrophobic modified silica sol is not dried, so that the filler is loaded on the surface of the secondary coating material, and the surface roughness of the regenerated coarse aggregate is increased by using the loading effect of the filler, so that the regenerated coarse aggregate is convenient to bond with cement paste, the density of the internal structure of the concrete is improved, and the mechanical strength of the concrete is improved.

The hydrophobic effect of the recycled coarse aggregate is further improved by using the means of coating the hydrophobic modified silica sol twice and matching with the filling and loading effects of gelatin substances, so that the finished concrete has better mechanical strength.

Preferably, the filler consists of titanium dioxide and composite fibers in a weight ratio of 0.6-1: 1.

By adopting the technical scheme, the titanium dioxide and the composite fiber are matched, the composite fiber is used as a supporting framework, and the titanium dioxide is used for filling, so that the surface of the regenerated coarse aggregate is fluffy, the roughness is improved, the smoothness of the surface of the regenerated aggregate coated with the hydrophobic modified silica sol is improved, the contact area with cement paste is increased, the bonding tightness of the regenerated coarse aggregate and the cement paste is improved, and the finished product has better mechanical strength.

Preferably, the composite fiber consists of glass fiber and alumina fiber in a weight ratio of 1: 1-3.

By adopting the technical scheme, the glass fiber and the alumina fiber are matched to play roles of drainage and diversion on the moisture on the surface of the regenerated coarse aggregate, and the hydrophobic effect of the hydrophobic modified silica sol is matched to ensure that the regenerated coarse aggregate has a better hydrophobic effect, so that the regenerated coarse aggregate is prevented from excessively absorbing water in concrete, and the finished product has better mechanical strength.

Glass fiber and alumina fiber are matched, and glass fiber is used as a supporting framework to be matched with the flexibility of alumina fiber, so that the alumina fiber is wound and coated on the surface of the secondary coating material, the better strength of the glass fiber is matched with the better elasticity of the alumina fiber, when the concrete generates cracks in advance, the cracks can be prevented from being generated, the anti-permeability performance of the concrete is ensured, and meanwhile, the concrete has better mechanical strength.

Preferably, the additive is a water reducing agent.

By adopting the technical scheme, the water reducing agent can effectively improve the fluidity of concrete, thereby facilitating the uniform contact of the recycled coarse aggregate with cement, fly ash, mineral powder and other substances and improving the mechanical strength of the concrete.

Preferably, the water reducing agent is a polycarboxylic acid high-efficiency water reducing agent.

By adopting the technical scheme, the finished product has better mechanical strength.

In summary, the present application has the following beneficial effects:

1. the surface of the regenerated aggregate is prevented from excessively absorbing water through the coating effect of the layer passing layer on the surface of the regenerated aggregate, so that the finished concrete has better mechanical strength, and the finished concrete has better mechanical strength by matching with better structural density.

2. By means of coating the hydrophobically modified silica sol twice, on one hand, hydration heat of concrete during hardening is prevented from damaging gelatin substances on the surface of the pretreated regenerated aggregate, and gelatin filling substances on the surface of the regenerated aggregate are damaged, so that the surface of the regenerated aggregate is easy to absorb water again, and the mechanical strength of the concrete is influenced; on the other hand, the connecting action of the hydrophobic modified silica sol is utilized, so that the filler is loaded on the surface of the pretreated recycled aggregate, and the surface roughness of the pretreated recycled aggregate is improved by the filler, so that the recycled coarse aggregate is convenient to bond with substances such as cement paste and the like, the density of the internal structure of the concrete is further improved, and the mechanical strength of the finished concrete is improved.

3. The glass fiber and the alumina fiber are matched to play a role in guiding and guiding water on the surface of the recycled coarse aggregate, and the hydrophobic effect of the hydrophobic modified silica sol is matched to ensure that the recycled coarse aggregate has a better hydrophobic effect, so that the recycled coarse aggregate is prevented from excessively absorbing water in concrete, and the finished concrete has better mechanical strength.

Detailed Description

The present application will be described in further detail with reference to examples.

Preparation example of Hydrophobically modified silica Sol

The silica sol in the following raw materials is purchased from alkaline silica sol produced by Shandong' an spring chemical technology Co., Ltd; methyltriethoxysilane was purchased from Shandong Polymer chemistry, Inc., technical grade; ethanol is purchased from industrial grade absolute ethanol produced by Shandong Taixi chemical company Limited, and the content is 99 percent; other raw materials and equipment are all sold in the market.

Preparation example 1: the hydrophobic modified silica sol is prepared by the following method:

weighing 10g of silica sol, adding into 90g of water, mixing and stirring to obtain a mixed solution; preserving the temperature for 8min under the condition of water bath at 45 ℃, then dripping 10mL of ethanol solution dissolved with 0.485g of methyltriethoxysilane into the mixed solution within 35min, reacting for 2.2h, and naturally cooling to prepare the hydrophobic modified silica sol.

Preparation example of recycled coarse aggregate

Titanium dioxide in the following raw materials was purchased from jinan silver lubricating chemical limited; the glass fiber is purchased from alkali-free glass fiber short shreds produced by Shandong Hongtai engineering materials, Inc., and the length of the glass fiber short shreds is 3 mm; the alumina fiber chopped strand is purchased from Jiahua crystal fiber GmbH of Zhejiang, and has a length of 5 mm; other raw materials and equipment are all sold in the market.

Preparation example 2: the recycled coarse aggregate is prepared by the following method:

i, crushing, cleaning, grading and drying waste concrete blocks to obtain a regenerated aggregate, wherein the regenerated aggregate comprises regenerated broken stones and regenerated sand, the particle size of the regenerated broken stones is 5-10cm, the mud content is 0.3%, the void ratio is 42%, the crushing index is 8%, and the surface density is 2510kg/m3(ii) a The fineness modulus of the reclaimed sand is 2.1, the mud content is 3 percent, the void ratio is 42 percent, and the surface density is 2460kg/m3

II, preparing a gelatin solution with the mass fraction of 0.45%, weighing 100kg of regenerated aggregate, soaking in 200kg of gelatin solution for 20min, continuously stirring at the rotating speed of 1500r/min in the soaking process, maintaining the temperature at 45 ℃ in the soaking process, taking out the regenerated aggregate after soaking, and then drying to obtain the pretreated regenerated aggregate;

III, weighing 10kg of the hydrophobic modified silica sol prepared in the preparation example 1, spraying the hydrophobic modified silica sol on the surface of 100kg of the pretreated regenerated aggregate, wherein the spraying amount of the hydrophobic modified silica sol is 10g/s, stirring the pretreated regenerated aggregate at the rotating speed of 1000r/min in the spraying process, and drying after spraying to prepare a primary coating material; weighing 15kg of the hydrophobic modified silica sol prepared in the preparation example 1, spraying the hydrophobic modified silica sol on the surface of 100kg of the primary coating material, wherein the spraying amount of the hydrophobic modified silica sol is 10g/s, stirring the primary coating material at the rotating speed of 1000r/min in the spraying process, and preparing a secondary coating material after spraying is finished; weighing 5.25kg of filler, spraying the filler on the surface of 100kg of secondary coating material, continuously stirring the secondary coating material at the rotating speed of 800r/min in the spraying process, wherein the filler is composed of 2.25kg of titanium dioxide and 3kg of composite fiber, the composite fiber is prepared by mixing 1kg of glass fiber and 2kg of alumina fiber, and drying after spraying to prepare the regenerated coarse aggregate.

Preparation example 3: the difference between the preparation example and the preparation example 2 is that:

II, preparing a gelatin solution with the mass fraction of 0.1%, weighing 100kg of regenerated aggregate, soaking in 150kg of gelatin solution for 15min, continuously stirring at the rotating speed of 800r/min in the soaking process, maintaining the temperature at 40 ℃ in the soaking process, taking out the regenerated aggregate after soaking, and then drying to obtain the pretreated regenerated aggregate;

III, weighing 5kg of the hydrophobic modified silica sol prepared in the preparation example 1, spraying the hydrophobic modified silica sol on the surface of 100kg of the pretreated regenerated aggregate, wherein the spraying amount of the hydrophobic modified silica sol is 10g/s, stirring the pretreated regenerated aggregate at the rotating speed of 1000r/min in the spraying process, and drying after spraying to prepare a primary coating material; then weighing 10kg of the hydrophobic modified silica sol prepared in the preparation example 1, spraying the hydrophobic modified silica sol on the surface of the primary coating material, wherein the spraying amount of the hydrophobic modified silica sol is 10g/s, stirring the primary coating material at the rotating speed of 1000r/min in the spraying process, and preparing a secondary coating material after spraying is finished; weighing 2kg of filler, spraying the filler on the surface of 100kg of secondary coating material, continuously stirring the secondary coating material at the rotating speed of 800r/min in the spraying process, mixing the filler with 0.75kg of titanium dioxide and 1.2kg of composite fiber, mixing the composite fiber with 0.625kg of glass fiber and 0.625kg of alumina fiber, and drying after the spraying is finished to prepare the regenerated coarse aggregate.

Preparation example 4: the difference between the preparation example and the preparation example 2 is that:

II, preparing a gelatin solution with the mass fraction of 0.7%, weighing 100kg of regenerated aggregate, placing the weighed regenerated aggregate into 250kg of gelatin solution, soaking for 25min, continuously stirring at the rotating speed of 1500r/min in the soaking process, keeping the temperature at 50 ℃ in the soaking process, taking out the regenerated aggregate after soaking, and then drying to obtain the pretreated regenerated aggregate;

III, weighing 15kg of the hydrophobic modified silica sol prepared in the preparation example 1, spraying the hydrophobic modified silica sol on the surface of 100kg of the pretreated regenerated aggregate, wherein the spraying amount of the hydrophobic modified silica sol is 10g/s, stirring the pretreated regenerated aggregate at the rotating speed of 1000r/min in the spraying process, and drying after spraying to prepare a primary coating material; then 20kg of the hydrophobic modified silica sol prepared in preparation example 1 is weighed and sprayed on the surface of the primary coating material, the spraying amount of the hydrophobic modified silica sol is 10g/s, the primary coating material is stirred at the rotating speed of 1000r/min in the spraying process, and a secondary coating material is prepared after the spraying is finished; weighing 10kg of filler, spraying the filler on the surface of 100kg of secondary coating material, continuously stirring the secondary coating material at the rotating speed of 800r/min in the spraying process, mixing the filler with 5kg of titanium dioxide and 5kg of composite fiber, mixing the composite fiber with 1.25kg of glass fiber and 3.75kg of alumina fiber, and drying after the spraying is finished to prepare the regenerated coarse aggregate.

Examples

Cement among the following raw materials was purchased from Sichuan Lisen building materials group, Inc.; the fly ash is purchased from a Guanghangming milling processing factory; the polycarboxylic acid high-efficiency water reducing agent is purchased from Chengdu Tianqin chemical industry, Limited liability company; other raw materials and equipment are all sold in the market.

Example 1: an inorganic recycled concrete aggregate:

252 parts of cement, 132 parts of fly ash, 44 parts of mineral powder, 1280 parts of recycled coarse aggregate, 6.5 parts of additive and 134 parts of water; the recycled coarse aggregate is the recycled coarse aggregate prepared in the preparation example 2; the additive is a water reducing agent, and the water reducing agent is a polycarboxylic acid high-efficiency water reducing agent; the cement is Portland cement with the strength grade of PO42.5R; the fly ash is I-grade fly ash, the ignition loss is less than or equal to 3.0 percent, the 45 mu m sieve allowance is less than or equal to 12 percent, and the water requirement is highThe ratio is less than or equal to 95 percent, and the water content is less than or equal to 1.0 percent; the ore powder is S95 grade ore powder, and the specific surface area of the ore powder is 400-450m2Kg, 28 days activity index 95%, fluidity 99%.

Example 2: the present embodiment is different from embodiment 1 in that:

200 parts of cement, 100 parts of fly ash, 60 parts of mineral powder, 950 parts of recycled coarse aggregate, 5 parts of additive and 110 parts of water; the water reducing agent is a naphthalene-based high-efficiency water reducing agent.

Example 3: the present embodiment is different from embodiment 1 in that:

280 parts of cement, 150 parts of fly ash, 20 parts of mineral powder, 1500 parts of recycled coarse aggregate, 8.4 parts of additive and 145 parts of water.

Example 4: the present embodiment is different from embodiment 1 in that:

the recycled coarse aggregate prepared in preparation example 3 was used as the recycled coarse aggregate.

Example 5: the present embodiment is different from embodiment 1 in that:

the recycled coarse aggregate prepared in preparation example 4 was used.

Example 6: the present embodiment is different from embodiment 1 in that:

the preparation process of the recycled coarse aggregate comprises the following steps:

III, weighing 10kg of the hydrophobic modified silica sol prepared in the preparation example 1, spraying the hydrophobic modified silica sol on the surface of 100kg of the pretreated regenerated aggregate, wherein the spraying amount of the hydrophobic modified silica sol is 10g/s, stirring the pretreated regenerated aggregate at the rotating speed of 1000r/min in the spraying process, and drying after spraying to prepare a primary coating material; weighing 5.25kg of filler, spraying the filler on the surface of 100kg of primary coating material, continuously stirring the primary coating material at the rotating speed of 800r/min in the spraying process, mixing the filler with 2.25kg of titanium dioxide, 1kg of glass fiber and 2kg of alumina fiber, and drying after spraying to obtain the regenerated coarse aggregate.

Example 7: the present embodiment is different from embodiment 1 in that:

the preparation process of the recycled coarse aggregate comprises the following steps:

III, weighing 15kg of the hydrophobic modified silica sol prepared in the preparation example 1, spraying the hydrophobic modified silica sol on the surface of the pretreated regenerated aggregate, wherein the spraying amount of the hydrophobic modified silica sol is 10g/s, stirring the pretreated regenerated aggregate at the rotating speed of 1000r/min in the spraying process, and preparing a secondary coating material after the spraying is finished; weighing 5.25kg of filler, spraying the filler on the surface of 100kg of secondary coating material, continuously stirring the secondary coating material at the rotating speed of 800r/min in the spraying process, mixing the filler with 2.25kg of titanium dioxide, 1kg of glass fiber and 2kg of alumina fiber, and drying after spraying to obtain the regenerated coarse aggregate.

Example 8: the present embodiment is different from embodiment 1 in that:

the preparation process of the recycled coarse aggregate comprises the following steps:

III, weighing 10kg of the hydrophobic modified silica sol prepared in the preparation example 1, adding the hydrophobic modified silica sol to the surface of 100kg of the pretreated regenerated aggregate at one time, and drying to prepare a primary coating material; then weighing 15kg of the hydrophobic modified silica sol prepared in the preparation example 1, adding the hydrophobic modified silica sol into the primary coating material at one time, and preparing a secondary coating material after the addition is finished; 5.25kg of filler is weighed and added into 100kg of secondary coating material at one time, the filler is prepared by mixing 2.25kg of titanium dioxide, 1kg of glass fiber and 2kg of alumina fiber, and then the mixture is dried to prepare the recycled coarse aggregate.

Example 9: the present embodiment is different from embodiment 1 in that:

the preparation process of the recycled coarse aggregate comprises the following steps:

III, weighing 10kg of the hydrophobic modified silica sol prepared in the preparation example 1, spraying the hydrophobic modified silica sol on the surface of 100kg of the pretreated regenerated aggregate, wherein the spraying amount of the hydrophobic modified silica sol is 10g/s, stirring the pretreated regenerated aggregate at the rotating speed of 1000r/min in the spraying process, and drying after spraying to prepare a primary coating material; and then 15kg of the hydrophobic modified silica sol prepared in the preparation example 1 is weighed and sprayed on the surface of the primary coating material, the spraying amount of the hydrophobic modified silica sol is 10g/s, the primary coating material is stirred at the rotating speed of 1000r/min in the spraying process, and the regenerated coarse aggregate is prepared after the spraying is finished and drying is carried out.

Example 10: the present embodiment is different from embodiment 1 in that:

the preparation process of the recycled coarse aggregate comprises the following steps:

the titanium dioxide is replaced by the composite fiber with the same mass in the filler raw material.

Example 11: the present embodiment is different from embodiment 1 in that:

the preparation process of the recycled coarse aggregate comprises the following steps:

the alumina fiber was replaced by glass fiber of equal mass in the filler material.

Comparative example

Comparative example 1: this comparative example differs from example 1 in that:

the preparation process of the recycled coarse aggregate comprises the following steps:

II, weighing 10kg of the hydrophobic modified silica sol prepared in the preparation example 1, spraying the hydrophobic modified silica sol on the surface of 100kg of regenerated aggregate, wherein the spraying amount of the hydrophobic modified silica sol is 10g/s, stirring the regenerated aggregate at the rotating speed of 1000r/min in the spraying process, and drying after the spraying is finished to prepare a primary coating material; weighing 15kg of the hydrophobic modified silica sol prepared in the preparation example 1, spraying the hydrophobic modified silica sol on the surface of the primary coating material, wherein the spraying amount of the hydrophobic modified silica sol is 10g/s, stirring the primary coating material at the rotating speed of 1000r/min in the spraying process, and preparing a secondary coating material after spraying is finished; weighing 5.25kg of filler, spraying the filler on the surface of 100kg of secondary coating material, continuously stirring the secondary coating material at the rotating speed of 800r/min in the spraying process, mixing the filler with 2.25kg of titanium dioxide, 1kg of glass fiber and 2kg of alumina fiber, and drying after spraying to obtain the regenerated coarse aggregate.

Comparative example 2: this comparative example differs from example 1 in that:

the preparation process of the recycled coarse aggregate comprises the following steps:

and II, preparing a gelatin solution with the mass fraction of 0.45%, weighing 100kg of regenerated aggregate, soaking in 200kg of the gelatin solution for 20min, continuously stirring at the rotating speed of 1500r/min in the soaking process, maintaining the temperature at 45 ℃ in the soaking process, taking out the regenerated aggregate after soaking, and drying to obtain the regenerated coarse aggregate.

Comparative example 3: this comparative example differs from example 1 in that:

the preparation process of the recycled coarse aggregate comprises the following steps: the hydrophobically modified silica sol prepared in preparation example 1 was replaced with silica sol of the same mass as the raw material.

Comparative example 4: this comparative example differs from example 1 in that:

the preparation process of the recycled coarse aggregate comprises the following steps:

i, crushing, cleaning, grading and drying waste concrete blocks to obtain the recycled coarse aggregate.

Performance test

1. Water absorption Performance test

Preparing recycled coarse aggregates by the preparation methods of example 1, examples 4 to 8 and comparative examples 1 to 4, respectively; then, the water absorption of the recycled coarse aggregate was measured by the method described in "test protocol for coarse aggregate density and water absorption", and data was recorded.

2. Detection of compressive strength properties

Adopting the raw materials of the examples 1-11 and the comparative examples 1-4, placing cement, fly ash, mineral powder and recycled coarse aggregate in a stirrer, stirring for 30s, then adding a water reducing agent and water, and continuing stirring for 20s to prepare a concrete standard test block; the compressive strength of the concrete prepared in examples 1-11 and comparative examples 1-4 at 7d and 28d is detected by referring to GB/T50081-2019 standard of mechanical property test method of common concrete, and data is recorded.

3. Flexural strength Property measurement

Adopting the raw materials of the examples 1-11 and the comparative examples 1-4, placing cement, fly ash, mineral powder and recycled coarse aggregate in a stirrer, stirring for 30s, then adding a water reducing agent and water, and continuing stirring for 20s to prepare a concrete standard test block; the flexural strength of the concrete prepared in examples 1-11 and comparative examples 1-4 at 7d and 28d is detected by referring to GB/T50081-2019 standard on mechanical property test method of common concrete, and data is recorded.

TABLE 1 Performance test Table

As can be seen by combining examples 1 and 2 to 3 with Table 1, the concrete obtained has a better mechanical strength.

It can be seen from the combination of example 1 and examples 4 to 5 and from Table 1 that the difference in the preparation method of the recycled coarse aggregate has an influence on the mechanical strength and water absorption of the concrete.

By combining the example 1 and the examples 6-11 and combining the table 1, it can be seen that the surface of the regenerated aggregate is not coated with the hydrophobic modified silica sol for the second time in the example 6 when the regenerated coarse aggregate is prepared, and the surface of the regenerated aggregate is not coated with the hydrophobic modified silica sol for the first time in the example 7 when the regenerated coarse aggregate is prepared, compared with the example 1, the water absorption rate of the regenerated coarse aggregate prepared in the examples 6 and 7 is greater than that of the example 1, the compressive strength and the flexural strength are both less than those of the example 1, which shows that the hydrophobic modified silica sol is coated for the first time, on one hand, the hydration heat of the concrete during hardening is prevented from damaging the gelatin substance on the surface of the pretreated regenerated aggregate, the gelatin filling substance on the surface of the regenerated aggregate is damaged, the surface of the regenerated aggregate is easy to absorb water again, and the mechanical strength of the concrete is influenced; on the other hand, the filler is loaded on the surface of the pretreated recycled aggregate by utilizing the connecting action of the hydrophobic modified silica sol, and the surface roughness of the pretreated recycled aggregate is improved by the filler, so that the recycled coarse aggregate is conveniently bonded with substances such as cement paste and the like, the density of the internal structure of the concrete is further improved, and the mechanical strength of the finished concrete is improved.

Example 8 when preparing a recycled coarse aggregate, the hydrophobically modified silica sol and the filler are added to the surface of the pretreated recycled aggregate by a one-time adding method, compared with example 1, the recycled coarse aggregate prepared in example 8 has a water absorption higher than that of example 1, and has a compressive strength and a flexural strength lower than those of example 1; the adding speed and the stirring time are limited in the adding process of the hydrophobic modified silica sol and the filler, so that the hydrophobic modified silica sol and the filler are uniformly loaded on the surface of the pretreated regenerated aggregate, the regenerated coarse aggregate has a good hydrophobic effect, and the regenerated coarse aggregate can be tightly combined with cement paste, so that the density of the internal structure of the concrete is improved, and the mechanical strength of the concrete is improved.

In the preparation process of the example 9, no filler is added, compared with the example 1, in the example 9, the compressive strength and the flexural strength of the concrete are both lower than those in the example 1, which shows that titanium dioxide and composite fiber are matched, the composite fiber is used as a supporting framework, and the titanium dioxide is used for filling, so that the surface of the regenerated coarse aggregate is fluffy, the roughness is improved, the smoothness of the surface of the regenerated aggregate coated with the hydrophobic modified silica sol is improved, the contact area with cement slurry is improved, the adhesion tightness of the regenerated coarse aggregate and the cement slurry is improved, and the finished product has better mechanical strength.

In example 10, the composite fiber with the same mass is used to replace titanium dioxide in the filler raw material, and compared with example 1, the compressive strength and the flexural strength of the concrete prepared in example 10 are both lower than those of example 1, which shows that after titanium dioxide is attached to the surface of the hydrophobically modified silica sol, the roughness of the surface of the secondary coating material is improved, so that the composite fiber is in contact with the secondary coating material, the composite fiber is supported on the surface of the secondary coating material, and the composite fiber is supported on the surface of the recycled coarse aggregate better, so that the mechanical strength of the concrete is improved.

Example 11 composite fiber raw material with equal mass of glass fiber replacing alumina fiber, compared with example 1, the concrete prepared in example 11 has compression strength and rupture strength smaller than those of example 1; the glass fiber and the alumina fiber are matched, the glass fiber is used as a supporting framework and matched with the flexibility of the alumina fiber, so that the alumina fiber is wound and coated on the surface of the secondary coating material, the better strength of the glass fiber is matched with the better elasticity of the alumina fiber, when the concrete generates cracks in advance, the cracks can be prevented from being generated, the impermeability of the concrete is ensured, and meanwhile, the concrete has better mechanical strength.

Combining example 1 and comparative examples 1-4 and combining table 1, it can be seen that the surface of the regenerated aggregate in comparative example 1 is not treated by gelatin solution during the preparation process of the regenerated coarse aggregate, compared with example 1, the water absorption of the regenerated coarse aggregate prepared in comparative example 1 is greater than that of example 1, and the compressive strength and the flexural strength of the concrete prepared in comparative example 1 are less than those of example 1; the regenerated aggregate can absorb gelatin solution, so that the gelatin solution can enter the internal pore structure of the regenerated aggregate and is coated on the surface of the regenerated aggregate, and gelatin filling materials are formed after the gelatin solution is dried, so that the gelatin filling materials are filled in the pores of the internal structure of the regenerated aggregate, and the regenerated aggregate is prevented from excessively absorbing mixing water in the concrete mixing process preliminarily by matching the covering effect of the gelatin, so that the mechanical strength of the concrete is ensured.

Comparative example 2 the surface of the pretreated regenerated aggregate is not treated by the hydrophobically modified silica sol in the preparation process of the regenerated coarse aggregate, and comparative example 3 the surface of the pretreated regenerated aggregate is treated by the silica sol in the preparation process of the regenerated coarse aggregate, compared with example 1, the water absorption of the regenerated coarse aggregate prepared in comparative examples 2 and 3 is greater than that of example 1, and the compressive strength and the flexural strength of the prepared concrete are less than those of example 1; the hydrophobic effect of the hydrophobic modified silica sol is utilized to enable adjacent recycled coarse aggregates to repel each other, so that the sand in the recycled coarse aggregates is conveniently filled in the space structure pores of the broken stones, and the cement is conveniently filled in the space structure pores of the adjacent sand of the recycled coarse aggregates, so that the compactness of the internal structure of the concrete is improved; and the hydrophobic effect is matched, so that the regenerated aggregate is further prevented from excessively absorbing the moisture in the concrete mixture, and the mechanical strength of the concrete is ensured.

Comparative example 4 the raw material in which the recycled aggregate was added to the raw material as the recycled coarse aggregate, compared to example 1, the recycled coarse aggregate prepared in comparative example 4 had a water absorption rate higher than that of example 1, and had a compressive strength and a flexural strength lower than those of example 1; the progressive coating and covering effects of the gelatin solution and the hydrophobic modified silicone adhesive on the surface of the regenerated aggregate are demonstrated, so that excessive water absorption on the surface of the regenerated aggregate can be effectively avoided, and the finished concrete has better mechanical strength by matching with better structural compactness.

The present embodiment is only for explaining the present application, and it is not limited to the present application, and those skilled in the art can make modifications of the present embodiment without inventive contribution as needed after reading the present specification, but all of them are protected by patent law within the scope of the claims of the present application.

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