&#; The Difference Between HPMC and MHEC
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Thermal Stability
Thermal stability of HPMC and MHEC is affected by their gel temperature. In general, the gel temperature of HPMC is around 60&#;-75&#; depending on its group content and different production technique. Due to the characteristics of MHEC group, it has a higher gel temperature, usually > 80&#;. Therefore its stability under high temperature is better that HPMC. On the other hand, because there are more hydrophilic groups in the structure of MHEC, it has better hydrophilicity. The water retention rate of MHEC in mortar is a little higher than HPMC at the same dosage of products with the same viscosity.
In practical construction, in the hot construction environment in summer, the water holding capacity of MHEC with the same viscosity and dosage is better than that of HPMC. Especially in the Southeast Asian countries and India, mortar will sometimes be constructed at high temperature. Cellulose ether with low gel temperature will lose its thickening and water retention at high temperature, thereby accelerating the hardening of mortar, and affects the construction.
Process Difference
HPMC is a non-ionic cellulose ether made from refined cotton after alkalization, using propylene oxide and methyl chloride as etherification agents, through a series of reactions; and MHEC is produced from refined cotton after alkalization treatment, using ethylene oxide and methyl chloride as etherification agents, after a series of reactions, because the storage and use risk factor of ethylene oxide is higher than that of propylene oxide, so The production technology and process requirements of MHEC are higher. There are fewer manufacturers and the price of MHEC is higher than that of HPMC.
Performance Index Difference
The gel temperature of MHEC is higher, generally the gel temperature can reach about 78-85 &#;; while the gel temperature of HPMC is generally about 60-75 &#;, so HPMC is not as effective as MHEC in high temperature resistance. This is the main reason why many customers in hot areas choose MHEC.
Generally speaking, the water retention of MHEC is higher than that of HPMC, but there is no big difference. Considering the cost and price, if there is not high requirements for the gel temperature, customers generally prefer HPMC. Furthermore, the viscosity stability, mildew resistance, and dispersibility of MHEC are generally higher than that of HPMC.
Application Difference
The application fields of HPMC and MHEC are basically the same. They are both widely used in construction mortar, putty, coatings, daily chemicals, ceramics, papermaking, etc. Among the real stone paint, the effect of using MHEC is better. These two products are mainly used in construction. The main difference is gel temperature. The high temperature resistance of MHEC is better.
The Similar Performances Between HPMC and MHEC in Construction Chemicals
Used as thickener, dispersant, water retention agent and air-entraining agent etc. Mainly used in cement and gypsum based dry mix mortar to increase bond strength, workability, and water retention. Reduce water loss on concrete surface, preventing cracks and increase scrape area. It is widely used in wall plaster and tile adhesive products
In paints, as a protective colloid, HPMC and MHEC can be used in the polymerization of vinyl acetate emulsion to improve the stability of the polymerization system in a wide pH range. Use pigments, fillers and other additives in finished product manufacturing to evenly disperse, stabilize and provide thickening effect.
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Cellulose ether is a general term for the reaction of alkali cellulose and etherifying agent to produce a series of products under certain conditions. Alkaline cellulose is replaced by different etherifying agents to obtain different cellulose ethers. According to the ionization properties of substituents, cellulose ethers can be divided into two categories: ionic (such as carboxymethyl cellulose) and non-ionic (such as methyl cellulose). According to the types of substituents, cellulose ethers can be divided into mono-ethers (such as methyl cellulose) and mixed ethers (such as hydroxypropyl methyl cellulose). According to different solubility, it can be divided into water solubility (such as hydroxyethyl cellulose) and organic solvent solubility (such as ethyl cellulose). Dry-mix mortar mainly uses water-soluble cellulose, which is divided into instant type and delayed-dissolve type after surface treatment.
The mechanism of action of cellulose ether in mortar is as follows:
(1) After the cellulose ether in the mortar is dissolved in water, the surface activity ensures that the gelling material is effectively and evenly distributed in the system. As a protective colloid, the cellulose ether "wraps" the solid particles and A layer of lubricating film is formed on the outer surface, which makes the mortar system more stable, and also improves the fluidity of the mortar during the mixing process and the smoothness of construction.
(2) The cellulose ether solution, due to its own molecular structure, makes the water in the mortar difficult to lose, and is gradually released over a long period of time, giving the mortar good water retention and workability.
If you are looking for more details, kindly visit hydroxyethyl methyl cellulose.
1. Methyl cellulose: (MC)
After the refined cotton is treated with alkali, chlorinated methane is used as an etherifying agent, and a series of reactions are carried out to produce cellulose ether. Generally, the degree of substitution is 1.6~2.0, and the solubility varies with the degree of substitution. Belongs to non-ionic cellulose ether.
(1) Methyl cellulose is soluble in cold water, and it is difficult to dissolve in hot water. Its aqueous solution is very stable in the range of pH=3~12. It has good compatibility with starch, guar gum, etc. and many surfactants. When the temperature reaches the gelation temperature, gelation will occur.
(2) The water retention of methyl cellulose depends on its addition, viscosity, particle fineness and dissolution rate. Generally, if the added amount is large, the fineness is small, and the viscosity is large, the water retention rate is high. Among them, the addition amount has the greatest influence on the water retention rate, and the viscosity is not proportional to the water retention rate. The dissolution rate mainly depends on the degree of surface modification of the cellulose particles and the fineness of the particles. Among the above cellulose ethers, methyl cellulose and hydroxypropyl methyl cellulose have higher water retention rates.
(3) The change of temperature will seriously affect the water retention rate of methyl cellulose. Generally, the higher the temperature, the worse the water retention. If the temperature of the mortar exceeds 40°C, the water retention of methyl cellulose will be significantly deteriorated, which will seriously affect the workability of the mortar.
(4) Methyl cellulose has a significant effect on the workability and adhesion of the mortar. The "adhesiveness" here refers to the adhesive force felt between the worker's application tool and the wall substrate, that is, the shear resistance of the mortar. The adhesiveness is large, the shear resistance of the mortar is large, and the force required by the workers in the use process is also large, and the workability of the mortar is poor. Among the cellulose ether products, the adhesion force of methyl cellulose is at a moderate level.
2. Hydroxypropyl methylcellulose (HPMC)
Hydroxypropyl methylcellulose is a cellulose variety whose output and consumption have been increasing rapidly in recent years. It is a non-ionic cellulose mixed ether made from refined cotton through a series of reactions using propylene oxide and methyl chloride as etherification agents after alkalization treatment. The degree of substitution is generally 1.2~2.0. Its properties are different by the ratio of methoxy content and hydroxypropyl content.
(1) Hydroxypropyl methylcellulose is easily soluble in cold water, and it is difficult to dissolve in hot water. But its gelation temperature in hot water is significantly higher than that of methyl cellulose. The dissolution in cold water is also greatly improved compared to methyl cellulose.
(2) The viscosity of hydroxypropyl methylcellulose is related to its molecular weight, and the higher the molecular weight, the higher the viscosity. Temperature also affects its viscosity, as the temperature increases, the viscosity decreases. But its high viscosity has a lower temperature effect than methyl cellulose. The solution is stable when stored at room temperature.
(3) The water retention of hydroxypropyl methyl cellulose depends on its addition amount, viscosity, etc. The water retention rate under the same addition amount is higher than that of methyl cellulose.
(4) Hydroxypropyl methylcellulose is stable to acid and alkali, and its aqueous solution is very stable in the range of pH=2~12. Caustic soda and lime water do not have much impact on its performance, but alkali can speed up its dissolution rate and slightly increase its viscosity. Hydroxypropyl methylcellulose is stable to general salts, but when the concentration of the salt solution is high, the viscosity of the hydroxypropyl methylcellulose solution tends to increase.
(5) Hydroxypropyl methylcellulose can be mixed with water-soluble polymer compounds to form a uniform and higher viscosity solution. Such as polyvinyl alcohol, starch ether, vegetable glue and so on.
(6) Hydroxypropyl methyl cellulose has better enzyme resistance than methyl cellulose, and its enzymatic degradation possibility in solution is lower than that of methyl cellulose.
(7) The adhesion of hydroxypropyl methyl cellulose to mortar construction is higher than that of methyl cellulose.
3. Hydroxyethyl cellulose (HEC)
It is made by reacting refined cotton with ethylene oxide as an etherifying agent in the presence of acetone after alkali treatment. The degree of substitution is generally 1.5~2.0. It has strong hydrophilicity and is easy to absorb moisture.
(1) Hydroxyethyl cellulose is soluble in cold water, but it is difficult to dissolve in hot water. Its solution is stable at high temperature and does not have gelling properties. It can be used for a longer time under high temperature in the mortar, but its water retention is lower than that of methyl cellulose.
(2) Hydroxyethyl cellulose is stable to general acids and alkalis. Alkali can accelerate its dissolution and slightly increase its viscosity. Its dispersibility in water is slightly worse than that of methyl cellulose and hydroxypropyl methyl cellulose.
(3) Hydroxyethyl cellulose has good anti-sagging performance for mortar, but has a longer retardation time for cement.
(4) The performance of hydroxyethyl cellulose produced by some domestic enterprises is significantly lower than that of methyl cellulose due to its high-water content and high ash content.
4. Carboxymethyl cellulose (CMC)
After alkali treatment of natural fibres (cotton, etc.), sodium mono-chloroacetate is used as an etherifying agent, and a series of reaction treatments are carried out to produce ionic cellulose ether. The degree of substitution is generally 0.4 to 1.4, and its performance is greatly affected by the degree of substitution.
(1) Carboxymethyl cellulose is highly hygroscopic, and it will contain a lot of moisture when stored under normal conditions.
(2) The carboxymethyl cellulose aqueous solution does not produce gel, and the viscosity decreases with the increase of temperature. When the temperature exceeds 50°C, the viscosity is irreversible.
(3) Its stability is greatly affected by pH. Generally, it can be used in gypsum-based mortar, but not in cement-based mortar. When it is highly alkaline, it loses its viscosity.
(4) Its water retention is much lower than that of methyl cellulose. It has retarding effect on gypsum-based mortar and reduces its strength. But the price of carboxymethyl cellulose is significantly lower than that of methyl cellulose.
For more information, please visit MHEC powder.
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