
Reasons and preventive measures for deterioration of polycarboxylate superplasticizer
Blog Reasons and preventi
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With economic development, the construction of highways and bridges has entered a new, higher stage. Its technical standards and quality requirements are becoming increasingly high and refined. Especially in optimizing concrete mix proportions, appropriate admixtures can be added, and the mix proportion can be formulated according to different construction and quality requirements. Whether guiding construction, controlling quality, or improving economic benefits, it will bring immeasurable convenience.
This article focuses on the relationship between high efficiency water reducing agents and concrete and its components.
Compatibility: Adding high efficiency water reducing agents can increase the fluidity of concrete. The slump of concrete increases with the increase of the dosage of high efficiency water reducing agent, and the maximum increase in slump occurs when the dosage reaches 0.75%. When the dosage is further increased, the slump increases, but the increase tends to be gentle.
The slump loss of concrete mixed with a high efficiency water reducing agent is very rapid, usually within 1 hour, and is even greater at high temperatures. The suitable dosage for general high efficiency water reducing agents is 0.5% to 0.75%. When the amount of cement is large, the suitable dosage is 0.9% to 1.2%. From an economic perspective, the commonly used dosage is around 0.5%.
Setting time: High efficiency water reducing agents have little effect on the setting time of concrete, and the degree of influence varies depending on the type and dosage of high-efficiency water reducing agents; The effect of high-efficiency water reducing agents on the setting of cement varies depending on the type of cement used. As shown in Table 1, the setting time of cement mixed with a high-efficiency water-reducing agent.
Bleeding: Adding high efficiency water reducing agents to concrete can reduce its bleeding rate, while using water reducing agents with causative properties (such as AF and Jian-1) can further reduce it. The concrete mixed with benchmark cement, with FDN, UNF and CRS added, and reduced water consumption, has a water bleeding rate of about 50% of the benchmark concrete.
Air content: Increase the air content of concrete. The air content of CRS, FDN, and UNF increased by about 1%, the content of AF and Jian-1 was 0.75%, and the air content of concrete was about 5%. Also note that adding high-efficiency water-reducing agents to flowing concrete will reduce its air content.
Hydration heat: The hydration heat and peak temperature of cement with a high-efficiency water reducing agent added are similar to those of cement without additives, but the appearance time of the peak is delayed by several hours. An efficient water-reducing agent reduces the heat of hydration of slag cement. Refer to Table 2 for the hydration heat of cement mixed with a high-efficiency water-reducing agent.
The experiment conducted by the Railway Science Research Institute shows that, under the same conditions, the flowability of cement slurry decreases with increasing cement fineness. When a small dose of water reducer is added, the flowability of the cement slurry still decreases sharply as cement fineness increases. However, when a 1% water reducer is added, the flowability of the cement slurry increases with increasing cement fineness. At the same time, when the specific surface area of cement is about 5000 cm2/g, adding 0.3% water reducer does not increase the flowability of the cement slurry. Only when the water reducer dosage is between 0.5% and 1.0% can the flowability of the cement slurry be significantly increased.
When the particle size of cement particles decreases, the flowability of cement slurry decreases. When a 1% water-reducing agent is added, the flowability of the cement slurry increases as the cement particle size decreases.
As the cement particle size decreases, the amount of water required to achieve the same fluidity increases, and the water reduction rate increases when the cement particle size is less than 10 μ m.
The fineness and quality of sand significantly affect the strength, water reduction rate, moisture content, and other properties of benchmark concrete and concrete with admixtures. When the fineness modulus of sand is 2.6-2.9, the water reduction rate is higher and very close; when the fineness modulus is 2.3 or 3.18, the water reduction rate is relatively low.
The water reduction rate of crushed stone concrete mixed with water-reducing agents is higher than that of pebble concrete.
Experiments conducted by the Water Resources Research Institute have shown that, maintaining the same water-cement ratio and workability, there is no significant difference in water reduction rate between crushed stone concrete and pebble concrete mixed with naphthalene-based high-efficiency water-reducing agents.
In summary, to prepare concrete that meets construction quality requirements for workability and is relatively economical, it is necessary to strictly control the raw materials. To meet the technical specifications, conduct more experiments and speak with data. Efficient water-reducing agents, cement, sand, and stone each have their own characteristics and influence one another; they are closely related. So we need to be familiar with their characteristics and their relationships, and make strategic plans in order to guide construction correctly and reasonably.

Reasons and preventive measures for deterioration of polycarboxylate superplasticizer
Blog Reasons and preventi