CN113527587A - Air-entraining type polycarboxylate superplasticizer and preparation method thereof - Google Patents

Abstract

An air-entraining type polycarboxylate superplasticizer and a preparation method thereof, wherein the raw material proportion for synthesizing the air-entraining type polycarboxylate superplasticizer is polyoxyethylene ether macromonomer 420; 3.5-14% of oleic acid; 44-81 parts of unsaturated carboxylic acid comonomer; 2.5-5% of an initiator; 0.6-1.2% of a reducing agent; 1.6-2.5 of a chain transfer agent; 1-2 parts of a catalyst; 9-30% of liquid caustic soda; 470-520 parts of water; the PH value of the air-entraining type polycarboxylate superplasticizer is 5-7, and the solid content is about 50%. The air-entraining type polycarboxylate superplasticizer disclosed by the invention is excellent in air-entraining performance, good in air-entraining capacity, adjustable in air-entraining performance and capable of obviously improving the workability of concrete. The water reducing agent has simple preparation process, short preparation time and low energy consumption.

Description

Air-entraining type polycarboxylate superplasticizer and preparation method thereof

Technical Field

The invention belongs to the technical field of building materials, and particularly relates to a concrete admixture and a preparation method thereof.

Background

Concrete is used as a building material with a huge amount in more and more fields, which puts higher requirements on various performances of the concrete. For fresh concrete, it is required to have excellent workability, and easy construction and pumping. The hardened concrete needs to have good durability, the strength meets the design requirement, the appearance is flat and attractive, and no honeycomb pitted surface exists. The gas content of the concrete is an important factor influencing the performance, and it is very important to introduce a large amount of tiny, uniform and stable bubbles into the concrete. The 'ball' and 'floating' effects of the bubbles can effectively improve the workability of the concrete, and the introduction of the bubbles can improve the pore structure of the hardened concrete and improve the cracking resistance and the freezing resistance.

The concrete air-entraining mode is to use an additive with air-entraining function. The traditional air-entraining admixture is a calcium lignosulfonate water reducing agent, but the water reducing rate of the water reducing agent is low, the mixing amount is large, the air entraining is too high, and the concrete strength is reduced. At present, the air-entraining admixture is mainly obtained by compounding the air-entraining agent and the polycarboxylic acid water reducing agent, but the problem of incompatibility of the air-entraining agent and the polycarboxylic acid can occur in the compounding process, so that the admixture is layered and the performance is reduced, on the other hand, the problem of poor adaptability of the air-entraining agent and a concrete material can occur, and in some materials, the air-entraining effect is poor. Therefore, more and more researchers have been studying the improvement of air-entraining properties of polycarboxylic acid from its molecular structure.

Chinese patent CN109867758A discloses an air-entraining type polycarboxylate water reducer and a synthesis process thereof, wherein under the condition of 90-130 ℃, fatty alcohol-polyoxyethylene ether and methacrylic acid are subjected to esterification for 5-8 hours to obtain an intermediate product, and then the intermediate product, HPEH, AMPS and methacrylic acid are subjected to polymerization for 3-4 hours to obtain the air-entraining type polycarboxylate water reducer. When the water reducing agent is added into C30 grade concrete with the addition amount of 0.17%, the air content is 1.4-2.0%, and the 28d strength reaches 37 Mpa.

The patent CN109134783A discloses an air-entraining polycarboxylate superplasticizer and a preparation method thereof, wherein under the condition of 65-70 ℃, unsaturated acid such as acrylic acid and unsaturated ester such as methyl acrylate are subjected to polymerization reaction for 2-3 h to obtain an intermediate product, and then the intermediate product and polyglycol monomethyl ether are subjected to esterification reaction for 5-6 h at 105-115 ℃ to obtain the air-entraining polycarboxylate superplasticizer. When the mixing amount of the water reducing agent in the dry and hard concrete is 0.6%, the air content is 1.6-5.0%.

Chinese patent CN104744684A discloses a block polyether, an air-entraining polycarboxylic acid water reducing agent prepared from the block polyether and a preparation method of the air-entraining polycarboxylic acid water reducing agent, wherein under the conditions of high temperature and high pressure, unsaturated monohydric alcohol, ethylene oxide and alkylene oxide of C3-C12 are subjected to polymerization reaction for 6-8 hours to obtain the block polyether, and then the block polyether, common polyether and unsaturated carboxylic acid are subjected to polymerization reaction for 4-6 hours at 50-80 ℃ to obtain the air-entraining polycarboxylic acid water reducing agent, and the water reducing agent enables the air content of mixed concrete to be 3-8.

The methods are all two-step methods for preparing the water reducing agent, the preparation process is complex, the reaction time is long, the energy consumption is high, and in esterification reaction and block polyether preparation reaction, concentrated sulfuric acid and other catalysts with strong corrosivity are needed, so that the dangerousness is high. On the other hand, the above method focuses only on the initial gas content of the concrete after using the air-entraining polycarboxylic acid, and does not focus on the change in gas content of the concrete with time. After the fresh concrete is placed, the air bubbles can be broken, and the air content is reduced. If the stability of the bubbles is poor, the loss of air content is too fast, the workability of concrete is rapidly reduced, the working performance is poor, and the construction is influenced.

Therefore, aiming at the defects of the prior art, it is necessary to provide a water reducing agent which has simple and efficient preparation method, is green and environment-friendly and has good gas content.

Disclosure of Invention

The invention aims to solve the defects of the prior art and provides the air-entraining type polycarboxylate water reducer which is simple in preparation process, short in preparation time, low in energy consumption, good in air entraining, small in air content loss and adjustable in air entraining capacity, and can obviously improve the air entraining performance of concrete, and the preparation method thereof.

The technical scheme adopted by the invention is as follows:

the air-entraining type polycarboxylate superplasticizer is prepared from the following raw materials in parts by weight:

polyoxyethylene ether macromonomer: 420;

oleic acid: 3.5 to 14;

unsaturated carboxylic acid comonomer: 44-81;

initiator: 2.5-5;

reducing agent: 0.6 to 1.2;

chain transfer agent: 1.6-2.5;

catalyst: 1-2;

liquid caustic soda: 9-30;

water: 470 to 520;

the PH value of the air-entraining type polycarboxylate superplasticizer is 5-7, and the solid content is about 50%.

Further, the reaction molar ratio of the unsaturated carboxylic acid comonomer to the polyoxyethylene ether macromonomer is (3.5-4.0): 1

Further, the polyoxyethylene ether macromonomer is one of allyl polyoxyethylene ether, methyl allyl polyoxyethylene ether and isopentenyl polyoxyethylene ether, and the molecular weight of the polyoxyethylene ether macromonomer is 2400.

Further, the molecular structural formula of the oleic acid is as follows:

further, the unsaturated carboxylic acid comonomer is one or more of acrylic acid, methacrylic acid and maleic acid.

Further, the initiator is one or more of hydrogen peroxide, ammonium persulfate and potassium persulfate with the mass concentration of 27%.

Further, the reducing agent is one or more of vitamin C, sodium sulfite, sodium formaldehyde sulfoxylate and E51.

Further, the chain transfer agent is one or more of mercaptoethanol, mercaptoacetic acid, mercaptopropionic acid and sodium hypophosphite.

Further, the catalyst is ferrous sulfate or ferrous chloride water solution with the mass concentration of 1%.

Further, the liquid alkali is sodium hydroxide or potassium hydroxide aqueous solution.

The preparation method of the air-entraining type polycarboxylate superplasticizer comprises the following steps:

(1) adding a polyoxyethylene ether macromonomer and water into a reaction kettle, heating to 60 ℃, and stirring until the polyoxyethylene ether macromonomer is completely dissolved to obtain a macromonomer solution;

(2) adding oleic acid into a reaction kettle, mixing with the macromonomer solution, and uniformly stirring;

(3) mixing unsaturated carboxylic acid comonomer with water, and stirring uniformly to obtain dropping liquid A;

(4) mixing a reducing agent, a chain transfer agent and water, and uniformly stirring to obtain a dropping liquid B;

(5) adding a catalyst and an initiator into a reaction kettle, stirring for 3-5 min, then simultaneously dropwise adding the solution A and the solution B, controlling the dropwise adding time of the solution A to be 120-150 min, controlling the dropwise adding time of the solution B to be 150-180 min, and after dropwise adding is finished, preserving heat for 20-30 min;

(6) and after the reaction is finished, adding liquid caustic soda and water, and adjusting the pH to 5-7 to obtain the air-entraining polycarboxylic acid water reducing agent with the solid content of about 50%.

Compared with the prior art, the invention has at least the following beneficial effects:

(1) the oleic acid structure is introduced into the air-entraining polycarboxylate superplasticizer disclosed by the invention, so that the formation of bubbles and the increase of the bubble stability are facilitated. Oleic acid is long-chain fatty acid, has extremely strong hydrophobicity, can reduce the hydrophilicity of polycarboxylic acid by introducing the oleic acid into the molecular structure of the polycarboxylic acid, obviously reduces the surface tension of the polycarboxylic acid, and is beneficial to the formation of bubbles. The introduction of the hydrophobic long straight chain reduces the diffusion rate of gas molecules in the bubbles, and the stability of the bubbles is also increased.

(2) The mole ratio of the unsaturated carboxylic acid comonomer to the polyether macromonomer influences the air entraining performance of the polycarboxylic acid, the air entraining performance is improved along with the increase of the acid-ether ratio, and the air entraining performance is optimal when the acid-ether ratio is (3.5-4.0): 1. The method controls the reaction molar ratio of the unsaturated carboxylic acid comonomer to the polyoxyethylene ether macromonomer to be (3.5-4.0): 1, and further improves the air entraining performance.

(3) The air entraining capacity is related to the addition amount of the oleic acid, and the more the oleic acid is added, the stronger the air entraining capacity is. The air entraining capacity of the polycarboxylate superplasticizer can be regulated and controlled by controlling the addition of the oleic acid.

(4) Oleic acid is unsaturated fatty acid, has double bonds in a molecular structure, can be directly polymerized with polyether monomers and unsaturated carboxylic acid small monomers, and omits the preparation process of intermediate products. The method adopts a simple one-step method to prepare the air-entraining type polycarboxylate superplasticizer, greatly shortens the reaction time, only needs about 3 hours in the whole process, and greatly improves the preparation efficiency.

(5) The air-entraining type polycarboxylate superplasticizer prepared by the invention can obviously improve the air-entraining performance of concrete, has good air-entraining performance and small air content loss, and has adjustable air-entraining capacity.

(6) The method has the advantages that the temperature in the whole preparation process is controlled to be 60 ℃, the temperature is lower, the energy consumption is low, and the method does not use harmful substances with strong corrosivity such as concentrated sulfuric acid and the like, and is more environment-friendly.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more apparent, the present invention is further described in detail with reference to the following embodiments. It should be understood that the specific embodiments described herein are merely illustrative of the invention and are not intended to limit the invention.

Example 1

Adding 420g of isopentenyl polyoxyethylene ether (with the molecular weight of 2400) and 300g of water into a four-mouth bottle reaction kettle, heating to 60 ℃, and stirring until all polyoxyethylene ether macromonomer is dissolved to obtain macromonomer solution; then 14g of oleic acid was added to the reactor, mixed with the macromonomer solution and stirred well. 81g of maleic acid was mixed with 99g of water to obtain solution A, and 1g of vitamin C and 2g of mercaptoethanol were mixed with 67g of water to obtain solution B. The reaction molar ratio of the isopentenyl polyoxyethylene ether to the maleic acid is 4.0: 1. Adding 2g of ferrous sulfate aqueous solution with the mass concentration of 1% into a reaction kettle, stirring for 3min, then adding 2g of hydrogen peroxide with the mass concentration of 27% and 2g of potassium persulfate, stirring for 5min, simultaneously beginning to dropwise add the solution A and the solution B, dropwise adding the solution A for 120min, dropwise adding the solution B for 150min, preserving the temperature for 30min after dropwise adding is finished, then adding 30g of sodium hydroxide solution with the mass concentration of 32% and 54g of water, and stirring to obtain the air-entraining type polycarboxylic acid water reducing agent with the pH of 6 and the solid content of 50%.

Example 2

Adding 420g of methyl allyl polyoxyethylene ether (molecular weight is 2400) and 300g of water into a reaction kettle, heating to 60 ℃, and stirring until all polyoxyethylene ether macromonomers are dissolved to obtain a macromonomer solution; then 3.5g of oleic acid was added to the reaction vessel, mixed with the macromonomer solution, and stirred uniformly. 44g of acrylic acid was mixed with 76g of water to obtain solution A, and 0.6g of sodium sulfite and 1.6g of thioglycolic acid were mixed with 57.8g of water to obtain solution B. The reaction molar ratio of the methallyl polyoxyethylene ether to the acrylic acid is 3.5: 1. Adding 1g of ferrous chloride aqueous solution with the mass concentration of 1% into a reaction kettle, stirring for 4min, then adding 2.5g of ammonium persulfate, stirring for 5min, simultaneously beginning to dropwise add the solution A and the solution B, dropwise adding the solution A for 150min, dropwise adding the solution B for 160min, keeping the temperature for 25min after dropwise adding is finished, then adding 18g of potassium hydroxide solution with the mass concentration of 32% and 36.2g of water, and stirring to obtain the air-entraining type polycarboxylate superplasticizer with the pH value of 6 and the solid content of 50%.

Example 3

Adding 420g of methyl allyl polyoxyethylene ether (molecular weight of 2400) and 300g of water into a four-mouth bottle reaction kettle, heating to 60 ℃, and stirring until all polyoxyethylene ether macromonomer is dissolved to obtain macromonomer solution; then 10.5g of oleic acid was added to the reaction vessel, mixed with the macromonomer solution, and stirred uniformly. Acrylic acid (30 g), maleic acid (30 g) and water (60 g) were mixed to obtain solution A, and sodium sulfite (0.5 g), E51 (0.2 g) and mercaptopropionic acid (1.6 g) and water (57.7 g) were mixed to obtain solution B. The reaction molar ratio of methallyl polyoxyethylene ether to acrylic acid + maleic acid was 3.9: 1. Adding 2g of ferrous chloride aqueous solution with the mass concentration of 1% into a reaction kettle, stirring for 5min, then adding 5g of ammonium persulfate, stirring for 5min, simultaneously beginning to dropwise add the solution A and the solution B, dropwise adding the solution A for 150min, dropwise adding the solution B for 160min, after dropwise adding, keeping the temperature for 25min, then adding 28g of potassium hydroxide solution with the mass concentration of 32% and 62g of water, and stirring to obtain the air-entraining type polycarboxylate superplasticizer with the pH of 7 and the solid content of 50%.

Example 4

Adding 420g of allyl polyoxyethylene ether (molecular weight of 2400) and 300g of water into a reaction kettle, heating to 60 ℃, and stirring until all polyoxyethylene ether macromonomers are dissolved to obtain a macromonomer solution; then 14g of oleic acid was added to the reactor, mixed with the macromonomer solution and stirred well. 56g of methacrylic acid and 64g of water were mixed to obtain solution A, and 1.2g of sodium formaldehyde sulfoxylate and 2.5g of sodium hypophosphite were mixed with 60g of water to obtain solution B. The reaction molar ratio of allyl polyoxyethylene ether to methacrylic acid was 3.7: 1. Adding 1.5g of ferrous sulfate aqueous solution with the mass concentration of 1% into a reaction kettle, stirring for 3min, then adding 3g of potassium persulfate, stirring for 5min, simultaneously beginning to dropwise add the solution A and the solution B, dropwise adding the solution A for 140min, dropwise adding the solution B for 160min, preserving the temperature for 20min after dropwise adding is finished, then adding 9g of potassium hydroxide solution with the mass concentration of 32% and 55g of water, and stirring to obtain the air-entraining type polycarboxylate superplasticizer with the pH value of 5 and the solid content of 50%.

Comparative example 1

To compare the effects of the present invention, the following comparative examples are provided, the preparation methods of which are as follows: adding 420g of isopentenyl polyoxyethylene ether and 300g of water into a four-mouth bottle reaction kettle, heating to 60 ℃, and stirring for dissolving. 81g of maleic acid was mixed with 99g of water to obtain solution A, and 1g of vitamin C and 2g of mercaptoethanol were mixed with 67g of water to obtain solution B. Adding 2g of ferrous sulfate aqueous solution with the mass concentration of 1% into a reaction kettle, stirring for 3min, then adding 4g of hydrogen peroxide with the mass concentration of 27% and 2g of potassium persulfate, stirring for 5min, simultaneously beginning to dropwise add the solution A and the solution B, dropwise adding the solution A for 120min, dropwise adding the solution B for 150min, preserving heat for 30min after dropwise adding is finished, then adding 30g of sodium hydroxide solution with the mass concentration of 32% and 54g of water, and stirring to obtain the polycarboxylic acid water reducer with the solid content of 50%. In this comparative example, compared to example 1, no oleic acid was added.

Comparative example 2

Adding 420g of methyl allyl polyoxyethylene ether and 300g of water into a reaction kettle, heating to 60 ℃, stirring for dissolving, adding 3.5g of oleic acid, and stirring uniformly. Acrylic acid (31.5 g) was mixed with water (88.5 g) to obtain solution A, and sodium sulfite (0.6 g) and thioglycolic acid (1.6 g) were mixed with water (57.8 g) to obtain solution B. Adding 1g of ferrous chloride aqueous solution with the mass concentration of 1% into a reaction kettle, stirring for 4min, then adding 2.5g of ammonium persulfate, stirring for 5min, simultaneously beginning to dropwise add the solution A and the solution B, dropwise adding the solution A for 150min, dropwise adding the solution B for 160min, preserving the temperature for 30min after dropwise adding is finished, then adding 18g of potassium hydroxide solution with the mass concentration of 32% and 36.2g of water, and stirring to obtain the polycarboxylic acid water reducer with the solid content of 50%. In this comparative example, the reaction molar ratio of methallyl polyoxyethylene ether to acrylic acid was 2.5:1, compared to example 2.

Comparative example 3

Adding 420g of methyl allyl polyoxyethylene ether and 300g of water into a four-mouth bottle reaction kettle, heating to 60 ℃, stirring for dissolving, adding 3.5g of oleic acid, and stirring uniformly. 56.7g of acrylic acid was mixed with 63.3g of water to obtain solution A, and 0.6g of sodium sulfite and 1.6g of thioglycolic acid were mixed with 57.8g of water to obtain solution B. Adding 2g of ferrous chloride aqueous solution with the mass concentration of 1% into a reaction kettle, stirring for 4min, then adding 2.5g of ammonium persulfate, stirring for 5min, simultaneously beginning to dropwise add the solution A and the solution B, dropwise adding the solution A for 150min, dropwise adding the solution B for 160min, keeping the temperature for 25min after dropwise adding is finished, then adding 18g of potassium hydroxide solution with the mass concentration of 32% and 36.2g of water, and stirring to obtain the polycarboxylic acid water reducer with the solid content of 50%. In this comparative example, the reaction molar ratio of methallyl polyoxyethylene ether to acrylic acid was 4.5:1, compared to example 2.

The air-entraining type polycarboxylate superplasticizer synthesized in the embodiment is compared with the polycarboxylate superplasticizer synthesized in the comparative example for concrete application performance, tests are carried out according to national standards GB 8076-2018 concrete admixture and GB/T50080-2016 common concrete mixture performance test method, and the initial slump, the expansion degree and the gas content of concrete, the gas content of 1h and the compressive strength of 28d are detected. The test materials are shown in table 1 as follows: jade bead cement P.O 42.5.5; machine-made sand, Mx is 2.6, MB is 1.0; river sand, Mx ═ 2.9; crushing stone, wherein the particle size is 5-20 mm, and continuously grading; mineral powder, grade S75; fly ash, class II.

TABLE 1C30 concrete mixing ratio

From the results of table 2 it can be seen that: the air-entraining type polycarboxylic acid water reducing agent synthesized in the examples 1-4 has high initial air content and low loss of air content for 1h, and the polycarboxylic acid prepared in the examples has excellent air-entraining performance and low loss of air content; comparing the relationship between the gas content and the oleic acid consumption of the 4 embodiments, it can be seen that the more the oleic acid consumption, the larger the gas content, the better the gas-entraining performance, and the gas-entraining capacity can be controlled by the oleic acid consumption; comparing the example 1 with the comparative example 1, it is obvious that the polycarboxylic acid prepared by adding oleic acid obviously improves the air entraining performance; comparing the acid ether ratio with 3.5-4.5, and the air entraining performance of the polycarboxylate superplasticizer is better; and fourthly, the polycarboxylate superplasticizer prepared in the embodiment obviously improves the workability of the concrete, and does not influence the strength of the concrete. Therefore, the air-entraining type polycarboxylate superplasticizer prepared in the embodiment has excellent air-entraining performance, small air content loss and adjustable air-entraining capacity, obviously improves the workability of concrete, and achieves the technical aim of the invention.

Table 2 concrete test data sheet

Claims (11)

1. The air-entraining type polycarboxylate superplasticizer is characterized by comprising the following raw materials in parts by weight:

polyoxyethylene ether macromonomer: 420;

oleic acid: 3.5 to 14;

unsaturated carboxylic acid comonomer: 44-81;

initiator: 2.5-5;

reducing agent: 0.6 to 1.2;

chain transfer agent: 1.6-2.5;

catalyst: 1-2;

liquid caustic soda: 9-30;

water: 470 to 520;

the PH value of the air-entraining type polycarboxylate superplasticizer is 5-7, and the solid content is about 50%.

2. The air-entraining type polycarboxylate superplasticizer according to claim 1, characterized in that the reaction molar ratio of the unsaturated carboxylic acid comonomer to the polyoxyethylene ether macromonomer is (3.5-4.0): 1.

3. The air-entraining type polycarboxylate superplasticizer according to claim 1, characterized in that the polyoxyethylene ether macromonomer is one of allyl polyoxyethylene ether, methyl allyl polyoxyethylene ether and isopentenyl polyoxyethylene ether, and has a molecular weight of 2400.

4. The air-entraining type polycarboxylate superplasticizer according to claim 1, characterized in that the molecular structural formula of oleic acid is as follows:

5. the air-entraining type polycarboxylate superplasticizer according to claim 1, characterized in that the unsaturated carboxylic acid comonomer is one or more of acrylic acid, methacrylic acid and maleic acid.

6. The air-entraining type polycarboxylate superplasticizer according to claim 1, characterized in that the initiator is one or more of hydrogen peroxide, ammonium persulfate and potassium persulfate.

7. The air-entraining type polycarboxylate superplasticizer according to claim 1, characterized in that the reducing agent is one or more of vitamin C, sodium sulfite, sodium formaldehyde sulfoxylate and E51.

8. The air-entraining type polycarboxylate superplasticizer according to claim 1, wherein the chain transfer agent is one or more of mercaptoethanol, mercaptoacetic acid, mercaptopropionic acid and sodium hypophosphite.

9. The air-entraining type polycarboxylate superplasticizer according to claim 1, characterized in that the catalyst is 1% by mass concentration of ferrous sulfate or ferrous chloride aqueous solution.

10. The air-entraining type polycarboxylate superplasticizer according to claim 1, characterized in that the liquid alkali is an aqueous solution of sodium hydroxide or potassium hydroxide.

11. The preparation method of the air-entraining type polycarboxylate superplasticizer according to any one of the claims 1 to 10, characterized by comprising the following steps:

(1) adding a polyoxyethylene ether macromonomer and water into a reaction kettle, heating to 60 ℃, and stirring until the polyoxyethylene ether macromonomer is completely dissolved to obtain a macromonomer solution;

(2) adding oleic acid into a reaction kettle, mixing with the macromonomer solution, and uniformly stirring;

(3) mixing unsaturated carboxylic acid comonomer with water, and stirring uniformly to obtain dropping liquid A;

(4) mixing a reducing agent, a chain transfer agent and water, and uniformly stirring to obtain a dropping liquid B;

(5) adding a catalyst and an initiator into a reaction kettle, stirring for 3-5 min, then simultaneously dropwise adding the solution A and the solution B, controlling the dropwise adding time of the solution A to be 120-150 min, controlling the dropwise adding time of the solution B to be 150-180 min, and after dropwise adding is finished, preserving heat for 20-30 min;

(6) and after the reaction is finished, adding liquid caustic soda and water, and adjusting the pH to 5-7 to obtain the air-entraining polycarboxylic acid water reducing agent with the solid content of about 50%.